Flexible circuit board and chip package including same

ABSTRACT

A flexible circuit board according to an embodiment of the present invention comprises: a substrate; a first wiring pattern layer disposed on a first surface of the substrate; a second wiring pattern layer disposed on a second surface opposite the first surface of the substrate; a first dummy pattern part disposed on the second surface of the substrate on which the second wiring pattern layer is not disposed; a first protection layer disposed on the first wiring pattern layer; and a second protection layer disposed on the second wiring pattern layer and the first dummy pattern part, wherein at least a part of the first dummy pattern part overlaps with the first wiring pattern layer in a vertical direction.

CROSS-REFERENCE TO RELATED PATENT APPLICATIONS

This application is a Continuation of U.S. patent application Ser. No.16/756,552, filed Apr. 16, 2020, which is a U.S. National StageApplication under 35 U.S.C. § 371 of PCT Application No.PCT/KR2018/012687, filed Oct. 25, 2018, which claims priority to KoreanPatent Application No. 10-2017-0145443, filed Nov. 2, 2017, whose entiredisclosures are hereby incorporated by reference.

TECHNICAL FIELD

An embodiment relates to a flexible circuit board for all-in-one chip onfilm and a chip package including the same.

Specifically, an embodiment relates to a flexible circuit board capableof mounting different types of chips on one substrate and a chip packageincluding the same.

BACKGROUND ART

Recently, various electronic products are thin, miniaturized, andlightened. Accordingly, a research for mounting a semiconductor chip ata high density in a narrow region of an electronic device is beingconducted in various ways.

Among them, since a chip on film (COF) method uses a flexible substrate,the COF method may be applied to both a flat panel display and aflexible display. That is, since the COF method may be applied tovarious wearable electronic devices, the COF method is attractingattention. In addition, since the COF method may realize a fine pitch,the COF method may be used to realize a high-resolution display (QHD asthe number of pixel increases.

A chip on film (COF) is a method in which a semiconductor chip ismounted on a flexible circuit board in the form of a thin film. Forexample, the semiconductor chip may be an integrated circuit (IC) chipor a large-scale integrated circuit (LSI) chip

Meanwhile, various chip-on-film package technologies using a flexiblesubstrate have been proposed as a high-density semiconductor chipmounting technology in order to respond to the trend of smaller size,thinness, and lighter weight in recent electronic products.

DISCLOSURE Technical Problem

An embodiment provides a flexible circuit board for all-in-one chip onfilm capable of mounting a plurality of chips on one substrate, a chippackage including the same, and an electronic device including the same.

An embodiment provides a flexible circuit board for all-in-one chip onfilm capable of removing pinholes generated during solder resistprinting, a chip package including the same, and an electronic deviceincluding the same.

An embodiment provides a flexible circuit board for all-in-one chip onfilm capable of designing a product in consideration of a solder resistprinting process, a chip package including the same, and an electronicdevice including the same.

Technical problems to be solved by the proposed embodiments are notlimited to the above-mentioned technical problems, and other technicalproblems not mentioned may be clearly understood by those skilled in theart to which the embodiments proposed from the following descriptionsbelong.

Technical Solution

A flexible circuit board according to an embodiment of the presentinvention includes: a substrate; a first wiring pattern layer disposedon a first surface of the substrate; a second wiring pattern layerdisposed on a second surface opposite to the first surface of thesubstrate; a first dummy pattern part disposed on the second surface ofthe substrate in which the second wiring pattern layer is not disposed;a first protection layer disposed on the first wiring pattern layer; anda second protection layer disposed on the second wiring pattern layerand the first dummy pattern part, wherein at least a part of the firstdummy pattern part is vertically overlapped with the first wiringpattern layer.

In addition, the flexible circuit board further includes a second dummypattern part which is disposed on the first surface of the substrate inwhich the first wiring pattern layer is not disposed and at least a partof which is vertically overlapped with the second wiring pattern layer.

Further, the first dummy pattern part has the same width as the firstwiring pattern layer, and one end thereof is disposed on the samevertical line as one end of the first wiring pattern layer.

Furthermore, the first dummy pattern part has a wider width than thefirst wiring pattern layer, and one end thereof is closer to one end ofthe substrate than one end of the first wiring pattern layer.

In addition, the first surface is an upper surface of the substrate, thesecond surface is a lower surface of the substrate, and the first dummypattern part is disposed more to the left than the first wiring patternlayer disposed on the leftmost side of the first wiring pattern layer.

Further, the second dummy pattern part is disposed more to the rightthan the second wiring pattern layer disposed on the rightmost side ofthe second wiring pattern layer.

In addition, the flexible circuit board further includes: a firstplating layer including tin (Sn) disposed on the first wiring patternlayer; and a second plating layer including tin (Sn) disposed on thesecond wiring pattern layer, wherein the first dummy pattern partincludes a first dummy pattern layer corresponding to the second wiringpattern layer, and a second dummy pattern layer corresponding to thesecond plating layer, and the second dummy pattern part includes a thirddummy pattern layer corresponding to the first wiring pattern layer, anda fourth dummy pattern layer corresponding to the first plating layer.

Meanwhile, a chip package according to an embodiment includes a flexiblecircuit board for all-in-one chip on film including: a substrate; aconductive pattern part disposed on the substrate; a dummy pattern partdisposed on the substrate; and a protective part disposed on one regionon the conductive pattern part and the dummy pattern part, wherein theconductive pattern part includes a first wiring pattern layer disposedon a first surface of the substrate, a first plating layer disposed onthe first wiring pattern layer, a second wiring pattern layer disposedon a second surface opposite to the first surface of the substrate, asecond plating layer disposed on the second wiring pattern layer,wherein a content of tin (Sn) of the plating layer in a first openregion of the protection layer is greater than that of the plating layerin a second open region of the protection layer, and a first chipdisposed in the first open region, and a second chip disposed in thesecond open region, wherein the dummy pattern part includes a firstdummy pattern part which is disposed on the second surface of thesubstrate on which the second wiring pattern layer is not disposed andat least a part of which is vertically overlapped with the first wiringpattern layer, and a second dummy pattern part which is disposed on thefirst surface of the substrate on which the first wiring pattern layeris not disposed and at least a portion of which is vertically overlappedwith the second wiring pattern layer.

In addition, the first surface is an upper surface of the substrate, thesecond surface is a lower surface of the substrate, the first dummypattern part is disposed more to the left than the first wiring patternlayer disposed on the leftmost side of the first wiring pattern layer,and the second dummy pattern part is disposed more to the right than thesecond wiring pattern layer disposed on the rightmost side of the secondwiring pattern layer.

In addition, the second chip is a drive IC chip, and the second chipincludes at least one of a diode chip, a power supply IC chip, a touchsensor IC chip, a multilayer ceramic capacitor (MLCC) chip, a ball gridarray (BGA) chip, and a chip condenser.

Meanwhile, an electronic device according to an embodiment of thepresent invention includes: a substrate; a conductive pattern partdisposed on the substrate; a dummy pattern part disposed on thesubstrate; and a protective part disposed partially in one region on theconductive pattern part, wherein the conductive pattern part includes afirst wiring pattern layer disposed on a first surface of the substrate,a first plating layer disposed on the first wiring pattern layer, asecond wiring pattern layer disposed on a second surface opposite to thefirst surface of the substrate, a second plating layer disposed on thesecond wiring pattern layer, a flexible circuit board for all-in-onechip on film in which a content of tin (Sn) of the plating layer in afirst open region of the protection layer is greater than that of theplating layer in a second open region of the protection layer; a displaypanel connected to one end of the flexible circuit board for all-in-onechip on film; and a main board connected to the other end of theflexible circuit board for all-in-one chip on film opposite to the oneend, wherein the dummy pattern part includes a first dummy pattern partwhich is disposed on the second surface of the substrate on which thesecond wiring pattern layer is not disposed and at least a part of whichis vertically overlapped with the first wiring pattern layer, and asecond dummy pattern part disposed on the first surface of the substrateon which the first wiring pattern layer is not disposed and at least apart of which is vertically overlapped with the second wiring patternlayer.

In addition, a first connection part and a second connection part aredisposed on a region different from the one region on the conductivepattern part, respectively, and a first chip is disposed on the firstconnection part and a second chip is disposed on the second connectionpart.

In addition, the display panel and the main board are disposed facingeach other, and the flexible circuit board for all-in-one chip on filmis disposed bending between the display panel and the main board.

Advantageous Effects

According to an embodiment of the present invention, different types offirst and second chips may be mounted on one flexible circuit board, andthus the embodiment may provide a chip package including a flexiblecircuit board for all-in-one chip on film with improved reliability.

According to an embodiment of the present invention, a display panel anda main board are directly connected by one flexible circuit board forall-in-one chip on film, and thus a size and thickness of the flexiblecircuit board for transmitting a signal generated from the display panelto the main board may be reduced, and accordingly, it is possible toincrease spaces of other components and/or a battery space.

According to an embodiment of the present invention, since connection ofa plurality of printed circuit boards is not required, convenience of aprocess and reliability of electrical connection may be improved, andaccordingly, it is possible to provide a flexible circuit board forall-in-one chip on film suitable for an electronic device having ahigh-resolution display unit.

In addition, according to an embodiment of the present invention, adummy pattern is disposed at a second surface of a substrate tocorrespond to a circuit pattern disposed on a first surface of thesubstrate, and a dummy pattern is disposed at the first surface of thesubstrate so as to correspond to a circuit pattern disposed on thesecond surface of the substrate, and thus it is possible to solve aproblem of solder resist not being applied or a problem of pinholes thatoccurs when printing the solder resist of the first surface or thesecond surface of the substrate.

DESCRIPTION OF DRAWINGS

FIG. 1A is a cross-sectional view of an electronic device including adisplay unit including a conventional printed circuit board.

FIG. 1B is a cross-sectional view of a form that the printed circuitboard according to FIG. 1A is bent.

FIG. 1C is a plan view of a form that the printed circuit boardaccording to FIG. 1A is bent.

FIG. 2A is a cross-sectional view of an electronic device including adisplay unit including a flexible circuit board for all-in-one chip onfilm according to an embodiment.

FIG. 2B is a cross-sectional view of a form that the flexible circuitboard for all-in-one chip on film according to FIG. 2A is bent.

FIG. 2C is a plan view of a form that the flexible circuit board forall-in-one chip on film according to FIG. 2A is bent.

FIG. 3A is a cross-sectional view of a chip package including adouble-side flexible circuit board for all-in-one chip on film accordingto an embodiment.

FIG. 3B is another cross-sectional view of a chip package including adouble-side flexible circuit board for all-in-one chip on film accordingto an embodiment.

FIG. 4A is a cross-sectional view of a flexible circuit board notincluding a dummy pattern part according to a comparative example.

FIG. 4B is a cross-sectional view of a flexible circuit board includinga lower dummy pattern part DP1 according to an embodiment of the presentinvention.

FIGS. 5A to 5D are views showing an example of various modifications ofthe lower dummy pattern part DP1 shown in FIG. 4B.

FIG. 6 is a view showing an upper dummy pattern part DP2 according to anembodiment of the present invention.

FIG. 7A is another cross-sectional view of a double-side flexiblecircuit board for all-in-one chip on film according to an embodiment.

FIG. 7B is a cross-sectional view of a chip package including adouble-side flexible circuit board for all-in-one chip on film accordingto FIG. 7A.

FIG. 8 is still another cross-sectional view of a chip package includinga double-side flexible circuit board for all-in-one chip on filmaccording to an embodiment.

FIG. 9 is an enlarged cross-sectional view of one region of adouble-side flexible circuit board for all-in-one chip on film accordingto an embodiment.

FIG. 10 is a plan view of the double-side flexible circuit board forall-in-one chip on film according to FIG. 7A.

FIG. 11 is a bottom view of the double-side flexible circuit board forall-in-one chip on film according to FIG. 7A.

FIGS. 12A and 12B are schematic plan views of a chip package includingthe double-side flexible circuit board for all-in-one chip on filmaccording to FIG. 7B.

FIGS. 13A, 13B, 14A, 14B, 15A and 15B are views showing a process ofmanufacturing the double-side flexible circuit board for all-in-one chipon film according to FIG. 7A into a chip package including thedouble-side flexible circuit board for all-in-one chip on film accordingto FIG. 7B.

FIG. 16 is a cross-sectional view of a chip package including thedouble-side flexible circuit board for all-in-one chip on film accordingto FIGS. 15A and 15B.

FIGS. 17 to 21 are views of various electronic devices including aflexible circuit board for all-in-one chip on film.

MODES OF THE INVENTION

In the description of embodiments, when it is described that each layer(film), region, pattern, or structure is formed “above/on” or“below/under” a substrate, each layer (film), region, pad or pattern,the description includes being formed both “directly” or “indirectly (byinterposing another layer)” “above/on” or “below/under”. A reference ofabove/on or below/under of each layer will be described with referenceto the drawings

In addition, when a certain part is referred to as being “connected” toanother part, it includes not only “directly connected” but also“indirectly connected” with another member therebetween. Further, when acertain part “includes” a certain component, unless described to thecontrary, this means that other components may not be excluded, butother components may be further provided.

In the drawings, a thickness or a size of each layer (film), region,pattern or structure may be modified for clarity and convenience ofexplanation, and thus does not entirely reflect the actual size

Hereinafter, embodiments of the present disclosure will be described indetail with reference to the accompanying drawings.

A printed circuit board according to a comparative example will bedescribed with reference to FIGS. 1A to 1C.

An electronic device having a display unit requires at least two printedcircuit boards to transmit display panel signals to a main board.

There may be at least two printed circuit boards included in theelectronic device including the display unit according to thecomparative example.

The electronic device including the display unit according to thecomparative example may include a first printed circuit board 10 and asecond printed circuit board 20.

The first printed circuit board 10 may be a flexible printed circuitboard. Specifically, the first printed circuit board 10 may be aflexible printed circuit board for chip on film (COF). The first printedcircuit board 10 may be a COF flexible printed circuit board on which afirst chip C1 is mounted. More specifically, the first printed circuitboard 10 may be a COF flexible printed circuit board for disposing adrive IC chip.

The second printed circuit board 20 may be a flexible printed circuitboard. Specifically, the second printed circuit board 20 may be aflexible printed circuit board (FPCB) for disposing a second chip C2which is a different type from that of the first chip C1. Here, thesecond chip C2 is other than the drive IC chip, and another chipexcluding the drive IC chip. It may refer to various chips such as asemiconductor element, a socket, and the like, which are disposed on theflexible printed circuit board for electrical connection. The secondprinted circuit board 20 may be a flexible printed circuit board (FPCB)for disposing a plurality of second chips C2. For example, the secondprinted circuit board 20 may be a flexible printed circuit board fordisposing a plurality of second chips C2A and C2B which are differenttypes.

The first printed circuit board 10 and the second printed circuit board20 may have different thicknesses. A thickness of the second printedcircuit board 20 may be smaller than that of the first printed circuitboard 10. For example, the first printed circuit board 10 may have athickness of about 20 μm to 100 μm. The second printed circuit board 20may have a thickness of about 100 μm to 200 μm. For example, a totalthickness t1 of the first printed circuit board 10 and the secondprinted circuit board may be 200 μm to 250 μm.

In the electronic device including the display unit according to acomparative example, the first and second printed circuit boards arerequired between the display panel and the main board, and thus anoverall thickness of the electronic device may be increased.Specifically, the electronic device including the display unit accordingto the comparative example requires the first and second printed circuitboards stacked vertically, and thus the overall thickness of theelectronic device may be increased.

The first printed circuit board 10 and the second printed circuit board20 may be formed by different processes. For example, the first printedcircuit board 10 may be manufactured by a roll-to-roll process. Thesecond printed circuit board 20 may be manufactured by using a sheetmethod.

Different types of chips are disposed on the first printed circuit board10 and the second printed circuit board 20, respectively, and a pitch ofa conductive pattern part for connection with each of chips may bedifferent from each other. For example, a pitch of a conductive patternpart disposed on the second printed circuit board 20 may be greater thanthat of a conductive pattern part disposed on the first printed circuitboard 10. For example, the pitch of the conductive pattern part disposedon the second printed circuit board 20 is 100 μm or more, and the pitchof the conductive pattern part disposed on the first printed circuitboard 10 may be less than 100 μm.

Specifically, the first printed circuit board 10 having a conductivepattern part disposed at a fine pitch may be process-efficientlymanufactured and reduce a process cost by a roll-to-roll process. On theother hand, the second printed circuit board 20 having a conductivepattern part disposed at a pitch of 100 μm or more is difficult to applythe roll-to-roll process, and thus has been generally manufactured in asheet process.

Since the first and second printed circuit boards according to thecomparative example are formed in different processes, processefficiency may be lowered.

In addition, since the chip package including the flexible circuit boardaccording to the comparative example has difficulty in a process ofdisposing different types of chips on one substrate, separate first andsecond printed circuit boards are required.

Further, the chip package including the flexible circuit board accordingto the comparative example has a problem that it is difficult to connectdifferent types of chips on one substrate.

Furthermore, in the flexible circuit board according to the comparativeexample, an upper circuit pattern and a lower circuit pattern aredesigned in consideration of only their respective signal transmissioncharacteristics. In other words, in the flexible circuit board accordingto the comparative example, the upper circuit pattern and the lowercircuit pattern are designed without considering the reliability of aprinting process of a protection layer (for example, solder resist)disposed on the outermost layer of a substrate. Therefore, in theflexible circuit board according to the comparative example, theprotection layer has a problem that a pin-hole is generated due to apositional difference between the upper circuit pattern and the lowercircuit pattern in the printing process.

Meanwhile, the first and second printed circuit boards may be disposedbetween the conventional display panel and main board.

In order to control, process, or transmit R, G, and B signals generatedfrom a display panel 30, the first printed circuit board 10 may beconnected to the display panel 30, the first printed circuit board 10may be again connected to the second printed circuit board 20, and thesecond printed circuit board 20 may be connected to a main board 40.

One end of the first printed circuit board 10 may be connected to thedisplay panel 30. The display panel 30 may be connected to the firstprinted circuit board 10 by an adhesive layer 50.

The other end opposite to the one end of the first printed circuit board10 may be connected to the second printed circuit board 20. The firstprinted circuit board 10 may be connected to the second printed circuitboard 20 by the adhesive layer 50.

One end of the second printed circuit board 20 may be connected to thefirst printed circuit board 10, and the other end opposite to the oneend of the second printed circuit board 20 may be connected to the mainboard 40. The second printed circuit board 20 may be connected to themain board 40 by the adhesive layer 50.

In the electronic device including the display unit according to thecomparative example, a separate adhesive layer 50 may be respectivelyrequired between the display panel 30 and the first printed circuitboard 10, the first printed circuit board 10 and the second printedcircuit board 20, and the second printed circuit board 20 and the mainboard 40. That is, in the electronic device including the display unitaccording to the comparative example, a plurality of adhesive layers arerequired, and thus there is a problem that reliability of the electronicdevice may be lowered due to poor connection of the adhesive layer. Inaddition, the adhesive layer disposed between the first printed circuitboard 10 and the second printed circuit board 20 connected verticallymay increase the thickness of the electronic device.

A first printed circuit board 10, a second printed circuit board 20, adisplay panel 30, and a main board 40 housed in an electronic deviceaccording to a comparative example will be described with reference toFIGS. 1B and 1C.

FIG. 1B is a cross-sectional view of a form that the printed circuitboard according to FIG. 1A is bent, and FIG. 1C is a plan view of alower surface of FIG. 1B.

The display panel 30 and the main board 40 may be disposed to face eachother. The first printed circuit board 10 including a bending region maybe disposed between the display panel 30 and the main board 40 disposedto face each other.

One region of the first printed circuit board 10 is bent, and the firstchip C1 may be disposed in a region thereof which is not bent.

In addition, the second printed circuit board 20 may be disposed to facethe display panel 30. The second chip C2 may be disposed in an unbendingregion of the second printed circuit board 20.

Referring to FIG. 1C, since the comparative example requires a pluralityof substrates, a length L1 in one direction may be a sum of lengths ofthe first printed circuit board 10 and the second printed circuit board20, respectively. The length L1 in one direction of the first printedcircuit board 10 and the second printed circuit board 20 may be a sum ofa short side length of the first printed circuit board 10 and a shortside length of the second printed circuit board 20. As an example, thelength L1 in one direction of the first printed circuit board 10 and thesecond printed circuit board 20 may be 30 mm to 40 mm. However, thelength L1 in one direction of the first printed circuit board 10 and thesecond printed circuit board 20 may have various sizes depending on atype of chip to be mounted and a type of electronic device.

In the electronic device according to the comparative example, since aplurality of printed circuit boards are required, a space for mountinganother component or a space for disposing a battery 60 may be reduced.

Recently, a component having various functions have been added to anelectronic device such as a smartphone in order to enhance userconvenience and security. For example, electronic devices such assmartphones and smart watches are equipped with a plurality of cameramodules (dual camera module, dual camera module), and a component havingvarious functions such as iris recognition and virtual reality (VR) isadded. Accordingly, it is important to secure a space for mounting theadded component.

In addition, various electronic devices such as wearable devices arerequired to increase a battery space in order to improve userconvenience.

Therefore, a plurality of printed circuit boards used in conventionalelectronic devices are replaced with a single printed circuit board, andthus importance of securing a space for mounting a new component orsecuring a space for increasing a battery size is emerged.

In the electronic device according to the comparative example, differenttypes of the first chip and the second chip may be disposed on the firstprinted circuit board 10 and second printed circuit board 30,respectively. Accordingly, there was a problem that a thickness of theadhesive layer 50 between the first printed circuit board 10 and thesecond printed circuit board 30 and a thickness of the second printedcircuit board 30 increase a thickness of the electronic device.

In addition, there was a problem that a battery space corresponding to asize of the second printed circuit board 30 or a space for mountingother components is reduced.

Further, there was a problem that poor bonding between the first andsecond printed circuit boards deteriorates reliability of the electronicdevice.

In order to solve such problems, embodiments may provide a new flexiblecircuit board for all-in-one chip on film capable of mounting aplurality of chips on one substrate, a chip package including the same,and an electronic device including the same. The same drawing numeralsin the embodiments and the comparative examples indicate the samecomponents, and redundant description with the comparative examplesdescribed above is omitted.

An electronic device including a flexible circuit board for all-in-onechip on film according to an embodiment will be described with referenceto FIGS. 2A to 2C.

The electronic device according to the embodiment may use one printedcircuit board in order to transmit a display panel signal to a mainboard. The printed circuit board included in the electronic deviceincluding a display unit according to the embodiment may be one flexibleprinted circuit board. Accordingly, a flexible circuit board 100 forall-in-one chip on film according to the embodiment may be bent betweenthe display unit and the main board facing each other to connect thedisplay unit and the main board.

Specifically, the flexible circuit board 100 for all-in-one chip on filmaccording to the embodiment may be one substrate for disposing aplurality of different types of chips.

The flexible circuit board 100 for all-in-one chip on film according tothe embodiment may be a substrate for disposing different types of afirst chip C1 and a second chip C2.

A thickness t2 of the flexible circuit board 100 for all-in-one chip onfilm according to the embodiment may be 20 μm to 100 μm. For example,the thickness t2 of the flexible circuit board 100 for all-in-one chipon film according to the embodiment may be 30 μm to 80 μm. For example,the thickness t2 of the flexible circuit board 100 for all-in-one chipon film according to the embodiment may be 50 μm to 75 μm. However, thethickness of the flexible circuit board 100 for all-in-one chip on filmaccording to the embodiment may be designed in various sizes dependingon a type of a chip and a type of an electronic device to be mounted.

Here, when the thickness t2 of the flexible circuit board 100 is lessthan 20 μm, the flexible circuit board 100 may be broken when it isfolded (or bent), and damage may occur due to heat or the like generatedin a mounted chip.

A thickness t2 of the flexible circuit board 100 for all-in-one chip onfilm according to the embodiment may have a thickness of ⅕ to ½ level ofthe thickness t1 of the plurality of first and second printed circuitboards according to the comparative example. That is, the thickness t2of the flexible circuit board 100 for all-in-one chip on film accordingto the embodiment may have a thickness of 20% to 50% level of thethickness t1 of the plurality of first and second printed circuit boardsaccording to the comparative example. For example, the thickness t2 ofthe flexible circuit board 100 for all-in-one chip on film according tothe embodiment may have a thickness of 25% to 40% level of the thicknesst1 of the plurality of first and second printed circuit boards accordingto the comparative example. For example, the thickness t2 of theflexible circuit board 100 for all-in-one chip on film according to theembodiment may have a thickness of 25% to 35% level of the thickness t1of the plurality of first and second printed circuit boards according tothe comparative example.

Since the electronic device including the display unit according to theembodiment requires only one flexible circuit board 100 for all-in-onechip on film between the display panel and the main board, the overallthickness of the electronic device may be reduced. Specifically, sincethe electronic device including the display unit according to theembodiment requires a single-layer printed circuit board, the overallthickness of the electronic device may be reduced.

In addition, the embodiment may omit the adhesive layer 50 between thefirst printed circuit board and the second printed circuit boardincluded in the comparative example, and thus the overall thickness ofthe chip package including the flexible circuit board for all-in-onechip on film and the electronic device including same may be reduced.

Further, since the embodiment may omit the adhesive layer 50 between thefirst printed circuit board and the second printed circuit board, aproblem due to the adhesion failure may be solved, thereby improvingreliability of the electronic device.

Furthermore, since a bonding process of a plurality of printed circuitboards may be omitted, process efficiency may be increased and a processcost may be reduced.

Furthermore, management of the substrate in a separate process isreplaced by management in one process, thereby improving the processefficiency and the product yield.

The flexible circuit board 100 for all-in-one chip on film according tothe embodiment may include a bending region and a non-bending region.The flexible circuit board 100 for all-in-one chip on film according tothe embodiment includes the bending region, thereby connecting thedisplay panel 30 and the main board 40 that are disposed to face eachother.

The non-bending region of the flexible circuit board 100 for all-in-onechip on film according to the embodiment may be disposed to face thedisplay panel 30. The first chip C1 and the second chip C2 may bedisposed on the non-bending region of the flexible circuit board 100 forall-in-one chip on film according to the embodiment. Accordingly, theflexible circuit board 100 for all-in-one chip on film according to theembodiment may stably mount the first chip C1 and the second chip C2.

FIG. 2C is a plan view of a lower surface in FIG. 2B.

Referring to FIG. 2C, since an embodiment requires one substrate, alength L2 in one direction may be a length of one substrate. The lengthL2 in one direction of a flexible circuit board 100 for all-in-one chipon film according to the embodiment may be a length of a short side ofthe flexible circuit board 100 for all-in-one chip on film according tothe embodiment. As an example, the length L2 in one direction of theflexible circuit board 100 for all-in-one chip on film according to theembodiment may be 10 mm to 50 mm. For example, the length L2 in onedirection of the flexible circuit board 100 for all-in-one chip on filmaccording to the embodiment may be 10 mm to 30 mm. For example, thelength L2 in one direction of the flexible circuit board 100 forall-in-one chip on film according to the embodiment may be 15 mm to 25mm. However, the embodiment is not limited thereto, and it is needlessto say that various sizes may be designed according to the type and/ornumber of chips to be disposed and the type of an electronic device. Thelength of the flexible circuit board may be reduced to 50 mm or less bymounting a plurality of chips on one board as in the embodiment. Whenthe length of the flexible circuit board is set to 10 mm or less, thedegree of freedom in designing of the plurality of chips to be mountedis reduced, and a space between the chips is narrow, and thus mutualelectrical characteristics may be affected

A length L2 in one direction of the flexible circuit board 100 forall-in-one chip on film according to the embodiment may have a length of50% to 70% level of a length L1 in one direction of the plurality offirst and second printed circuit boards according to the comparativeexample. For example, the length L2 in one direction of the flexiblecircuit board 100 for all-in-one chip on film according to theembodiment may have a length of 55% to 70% level of the length L1 in onedirection of the plurality of first and second printed circuit boardsaccording to the comparative example. The length L2 in one direction ofthe flexible circuit board 100 for all-in-one chip on film according tothe embodiment may have a length of 60% to 70% level of the length L1 inone direction of the plurality of first and second printed circuitboards according to the comparative example.

Accordingly, in the embodiment, a size of a chip package including theflexible circuit board 100 for all-in-one chip on film in the electronicdevice may be reduced, so that a space for disposing a battery 60 may beincreased. In addition, the chip package including the flexible circuitboard 100 for all-in-one chip on film according to the embodiment mayreduce a plane area, so that a space for mounting other components maybe secured.

Hereinafter, a flexible circuit board 100 for all-in-one chip on filmaccording to an embodiment and a chip package thereof will be describedwith reference to the drawings.

FIG. 3A is a cross-sectional view of a flexible circuit board accordingto a first embodiment of the present invention, FIG. 3B is a modifiedexample of the flexible circuit board of FIG. 3A, FIG. 4A is across-sectional view of a flexible circuit board not including a dummypattern part according to a comparative example, FIG. 4B is across-sectional view of a flexible circuit board including a lower dummypattern part DP1 according to an embodiment of the present invention,FIGS. 5A to 5D are views showing an example of various modifications ofthe lower dummy pattern part DP1 shown in FIG. 4B, FIG. 6 is a viewshowing an upper dummy pattern part DP2 according to an embodiment ofthe present invention, FIG. 7A is another cross-sectional view of adouble-side flexible circuit board for all-in-one chip on film accordingto an embodiment, FIG. 7B is a cross-sectional view of a chip packageincluding a double-side flexible circuit board for all-in-one chip onfilm according to FIG. 7A, and FIG. 8 is still another cross-sectionalview of a chip package including a double-side flexible circuit boardfor all-in-one chip on film according to an embodiment.

Referring to FIGS. 3A, 3B, 4A, 4B, 5A, 5B, 5C, 5D, 6, 7A, 7B, and 8 ,the flexible circuit board 100 for all-in-one chip on film according tothe embodiment may be a double-side flexible circuit board forall-in-one chip on film having electrode pattern parts on both sidesthereof.

The flexible circuit board 100 for all-in-one chip on film according tothe embodiment may include a substrate 110, a wiring pattern layer 120disposed on the substrate 110, a plating layer 130, an upper dummypattern part DP2, a lower dummy pattern part DP1, and a protection layer140.

After the wiring pattern layer 120, the plating layer 130, the upperdummy pattern part DP2, and the protection layer 140 are disposed on onesurface of the substrate 110 according to the embodiment, the wiringpattern layer 120, the plating layer 130, the lower dummy pattern partDP1, and the protection layer 140 are disposed on the other surfaceopposite to the one surface of the substrate 110.

That is, an upper wiring pattern layer, an upper plating layer, theupper dummy pattern part DP2, and an upper protection layer may bedisposed on one surface of the substrate 110 according to theembodiment, and a lower wiring pattern layer, a lower plating layer, thelower dummy pattern part DP1, and a lower protection layer are disposedon the other surface opposite to the one surface of the substrate 110.

The upper wiring pattern layer may include a metal materialcorresponding to the lower wiring pattern layer. Accordingly, processefficiency may be improved. However, it is needless to say that theembodiment is not limited thereto, and may include other conductivematerials.

A thickness of the upper wiring pattern layer may correspond to athickness of the lower wiring pattern layer. Accordingly, processefficiency may be improved.

The upper plating layer may include a metal material corresponding tothe lower plating layer. Accordingly, process efficiency may beimproved. However, it is needless to say that the embodiment is notlimited thereto, and may include other conductive materials.

A thickness of the upper plating layer may correspond to a thickness ofthe lower plating layer. Accordingly, process efficiency may beimproved.

The upper dummy pattern part DP2 is disposed at a position correspondingto the lower wiring pattern layer disposed on a lower surface of thesubstrate 110 of the upper surface of the substrate 110, and the lowerdummy pattern part DP1 is disposed at a position corresponding to theupper wiring pattern layer disposed on the upper surface of thesubstrate 110 of the lower surface of the substrate 110. Accordingly, inthe present invention, a pin-hole problem caused by a difference inheight of the upper and lower portions of the substrate 110 in aprinting process of the upper protection layer or the lower protectionlayer may be solved, thereby improving reliability of a printed circuitboard.

The substrate 110 may be a supporting substrate for supporting thewiring pattern layer 120, the plating layer 130, and the protectionlayer 140.

The first substrate 110 may include a bending region and a region otherthan the bending region. That is, the substrate 110 may include abending region in which bending is performed and a non-bending regionother than the folding region

The substrate 110 may be a flexible substrate. Accordingly, thesubstrate 110 may be partially bent. That is, the substrate 110 mayinclude a flexible plastic. For example, the substrate 110 may be apolyimide (PI) substrate. However, the embodiment is not limitedthereto, and may be a substrate made of a polymer material such aspolyethylene terephthalate (PET), polyethylene naphthalate (PEN), or thelike. Accordingly, a flexible circuit board including the substrate 110may be used in various electronic devices having a curved displaydevice. For example, a flexible circuit board including the substrate110 is excellent in flexible characteristics, thereby having suitabilityof mounting a semiconductor chip on a wearable electronic device. Inparticular, the embodiment may be suitable for an electronic deviceincluding a curved display.

The substrate 110 may be an insulating substrate. That is, the substrate110 may be an insulating substrate supporting various wiring patterns.

The substrate 110 may have a thickness of 20 μm to 100 μm. For example,the substrate 110 may have a thickness of 25 μm to 50 μm. For example,the substrate 100 may have a thickness of 30 μm to 40 μm. When thethickness of the substrate 100 exceeds 100 μm, the thickness of theentire flexible circuit board may be increased. When the thickness ofthe substrate 100 is less than 20 μm, it may be difficult to dispose thefirst chip C1 and the second chip C2 at the same time. When thethickness of the substrate 110 is less than 20 μm, the substrate 110 maybe vulnerable to heat/pressure in a process of mounting a plurality ofchips, and thus it is difficult to dispose the plurality of chips at thesame time. A wiring may be disposed on the substrate 110. The wiring maybe a plurality of patterned wirings. For example, the plurality ofwirings on the substrate 110 may be disposed to be spaced apart fromeach other. That is, a wiring pattern layer 120 may be disposed on onesurface of the substrate 110.

An area of the substrate 110 may be larger than that of the wiringpattern layer 120. Specifically, a planar area of the substrate 110 maybe larger than that of the wiring pattern layer 120. That is, the wiringpattern layer 120 may be partially disposed on the substrate 110. Forexample, a lower surface of the wiring pattern layer 120 may be incontact with the substrate 110, and the substrate 110 may be exposedbetween the plurality of wirings. The wiring pattern layer 120 mayinclude a conductive material.

The substrate 110 may include a through-hole. The substrate 110 mayinclude a plurality of through-holes. The plurality of through-holes ofthe substrate 110 may be formed individually or simultaneously by amechanical process or a chemical process. For example, the plurality ofthrough-holes of the substrate 110 may be formed by a drilling processor an etching process. As an example, the through-holes of the substratemay be formed through laser punching and desmearing processes. Thedesmearing process may be a process of removing a polyimide smearattached to an inner surface of the through-hole. By the desmearingprocess, an inner surface of the polyimide substrate may have aninclined surface similar to a straight line.

The wiring pattern layer 120, the plating layer 130, and the protectionlayer 140 may be disposed on the substrate 110. In detail, the wiringpattern layer 120, the plating layer 130, and the protection layer 140may be sequentially disposed on both surfaces of the substrate 110. Atthis time, the dummy pattern parts DP1 and DP2 have heightscorresponding to the wiring pattern layer 120 and the plating layer 130.Preferably, the dummy pattern parts DP1 and DP2 in the first embodimentof the present invention are formed of the same metal material as thewiring pattern layer 120, and may have a greater thickness than thewiring pattern layer 120. Preferably, the dummy pattern parts DP1 andDP2 may have a thickness obtained by combining the thickness of thewiring pattern layer 120 and the thickness of the plating layer 130.

The wiring pattern layer 120 may be formed by at least one method ofevaporation, plating, and sputtering.

As an example, a wiring layer for forming a circuit may be formed byelectrolytic plating after sputtering. For example, a wiring layer forforming a circuit may be a copper plating layer formed by electrolessplating. Alternatively, the wiring layer may be a copper plating layerformed by electroless plating and electrolytic plating.

Next, a patterned wiring layer may be formed on both surfaces of aflexible circuit board, that is, on the upper and lower surfaces, afterlaminating a dry film on the wiring layer, through the processes ofexposure, development, and etching. And thus the wiring pattern layer120 may be formed.

For example, the wiring pattern layer 200 may include a metal materialhaving excellent electrical conductivity. More specifically, the wiringpattern layer 200 may include copper (Cu). However, the embodiment isnot limited thereto, and it is possible to include at least one metalamong copper (Cu), aluminum (Al), chromium (Cr), nickel (Ni), silver(Ag), molybdenum (Mo), gold (Au), titanium (Ti), and an alloy thereof.

The wiring pattern layer 120 may be disposed to have a thickness of 1 μmto 15 μm. For example, the wiring pattern layer 120 may be disposed tohave a thickness of 1 μm to 10 μm. For example, the wiring pattern layer120 may be disposed to have a thickness of 2 μm to 10 μm.

When the thickness of the wiring pattern layer 120 is less than 1 μm, aresistance of the wiring pattern layer may increase. When the thicknessof the wiring pattern layer 120 exceeds 10 μm, it is difficult torealize a fine pattern.

Conductive materials may be filled in via holes V1, V2, and V3 passingthrough the substrate 110. The conductive material filled in a via holemay correspond to the wiring pattern layer 120, or may be differentconductive materials. For example, the conductive material filled in avia hole may include at least one metal among copper (Cu), aluminum(Al), chromium (Cr), nickel (Ni), silver (Ag), molybdenum (Mo), gold(Au), titanium (Ti), and an alloy thereof. The electrical signal of aconductive pattern part CP on the upper surface of the substrate 110 maybe transmitted to the conductive pattern part CP of the lower surface ofthe substrate 110 through the conductive material filled in a via hole.

Next, a plating layer 130 may be formed on the wiring pattern layer 120.The plating layer 130 may include a first plating layer 131 and a secondplating layer 132.

The first plating layer 131 may be disposed on the wiring pattern layer120, and the second plating layer 132 may be disposed on the firstplating layer 131. The first plating layer 131 and the second platinglayer 132 may be formed in two layers on the wiring pattern layer 120 inorder to prevent formation of whiskers. Accordingly, a short circuitbetween patterns of the wiring pattern layer 120 may be prevented. Inaddition, since two plating layers are disposed on the wiring patternlayer 120, bonding characteristics with the chip may be improved. Whenthe wiring pattern layer includes copper (Cu), the wiring pattern layermay not be directly bonded to the first chip C1, and a separate bondingprocess may be required. On the other hand, when the plating layerdisposed on the wiring pattern layer includes tin (Sn), a surface of theplating layer may be a pure tin layer, and thus bonding with the firstchip C1 may be facilitated. At this time, a wire connected to the firstchip C1 may be simply connected to the pure tin layer only by heat andpressure, and thus accuracy of wire bonding of the chip and convenienceof a manufacturing process may be improved.

A region in which the first plating layer 131 is disposed may correspondto a region in which the second plating layer 132 is disposed. That is,an area in which the first plating layer 131 is disposed may correspondto an area in which the second plating layer 132 is disposed.

The plating layer 130 may include tin (Sn). For example, the firstplating layer 131 and the second plating layer 132 may include tin (Sn).

As an example, the wiring pattern layer 120 may be formed of copper(Cu), and the first plating layer 131 and the second plating layer 132may be formed of tin (Sn). When the plating layer 130 includes tin,corrosion resistance of tin (Sn) is excellent, and thus the wiringpattern layer 120 may be prevented from being oxidized.

Meanwhile, a material of the plating layer 130 may have a lowerelectrical conductivity than that of the wiring electrode layer 120. Theplating layer 130 may be electrically connected to the wiring electrodelayer 120.

The first plating layer 131 and the second plating layer 132 may beformed of the same tin (Sn), but may be formed in a separate process.

For example, when the manufacturing process of a flexible circuit boardaccording to the embodiment includes a heat treatment process such asthermal curing, a diffusion action of copper (Cu) of the wiring patternlayer 120 or tin (Sn) of the plating layer 130 may occur. Specifically,the diffusion action of copper (Cu) of the wiring pattern layer 120 ortin (Sn) of the plating layer 130 may occur by curing of the protectionlayer 140.

Accordingly, as the diffusion concentration of copper (Cu) decreasesfrom the first plating layer 131 to a surface of the second platinglayer 132, a content of copper (Cu) may be continuously reduced.Meanwhile, the content of tin (Sn) may continuously increase from thefirst plating layer 131 to the surface of the second plating layer 132.Accordingly, the uppermost portion of the plating layer 130 may includea pure tin layer.

That is, the wiring pattern layer 120 and the plating layer 130 may bean alloy of tin and copper due to a chemical action at a stackinginterface. The thickness of the alloy of tin and copper after theprotection layer 140 is cured on the plating layer 130 may be increasedthan the thickness of the alloy of tin and copper after the platinglayer 130 is formed on the wiring pattern layer 120.

An alloy of tin and copper included in at least a part of the platinglayer 130 may have a chemical formula of Cu_(x)Sn_(y), and may be0<x+y<12. For example, in the chemical formula, a sum of x and y may be4≤x+y≤11. For example, the alloy of tin and copper included in theplating layer 130 may include at least one of Cu₃Sn and Cu₆Sn₅.Specifically, the first plating layer 131 may be an alloy layer of tinand copper.

In addition, the first plating layer 131 and the second plating layer132 may have different contents of tin and copper. The first platinglayer 131 in direct contact with the copper wiring pattern layer mayhave a copper content greater than that of the second plating layer 132.

The second plating layer 132 may have a higher tin content than thefirst plating layer 131. The second plating layer 132 may include a puretin layer. Here, pure tin may mean that a content of tin (Sn) is 50atomic % or more, 70 atomic % or more, or 90 atomic % or more. At thistime, an element other than tin may be copper. For example, the secondplating layer 132 may have a tin (Sn) content of 50 atomic % or more.For example, the second plating layer 132 may have a tin (Sn) content of70 atomic % or more. For example, the second plating layer 132 may havea tin (Sn) content of 90 atomic % or more. For example, the secondplating layer 132 may have a tin (Sn) content of 95 atomic % or more.For example, the second plating layer 132 may have a tin (Sn) content of98 atomic % or more.

The plating layer according to the embodiment may preventelectrochemical migration resistance due to a diffusion phenomenon ofCu/Sn, and may prevent short-circuit defects due to metal growth.

However, the embodiment is not limited thereto, and the plating layer130 may include any one of a Ni/Au alloy, gold (Au), electroless nickelimmersion gold (ENIG), a Ni/Pd alloy, and organic solderabilitypreservative (OSP).

The first plating layer 131 and the second plating layer 132 maycorrespond to each other, or have different thicknesses. The totalthickness of the first plating layer 131 and the second plating layer132 may be 0.3 μm to 1 μm. The total thickness of the first platinglayer 131 and the second plating layer 132 may be 0.3 μm to 0.7 μm. Thetotal thickness of the first plating layer 131 and the second platinglayer 132 may be 0.3 μm to 0.5 μm. Any one plating layer of the firstplating layer 131 and the second plating layer 132 may have a thicknessof 0.05 μm to 0.15 μm. For example, any one plating layer of the firstplating layer 131 and the second plating layer 132 may have a thicknessof 0.07 μm to 0.13 μm.

Thereafter, the protective part PP may be screen-printed on theconductive pattern part CP.

The protection layer 140 may be partially disposed on the wiring patternlayer 120. For example, the protection layer 140 may be disposed on theplating layer 130 on the wiring pattern layer 120. Since the protectionlayer 140 may cover the plating layer 130, it is possible to preventdamage or delamination of a film caused by oxidation of the wiringpattern layer 120 and the plating layer 130.

The protection layer 140 may be partially disposed in a region excludinga region in which the wiring pattern layer 120 and/or the plating layer130 is electrically connected to a display panel 30, a motherboard 40, afirst chip C1, or a second chip C2.

Accordingly, the protection layer 140 may be partially overlapped withthe wiring pattern layer 120 and/or the plating layer 130.

An area of the protection layer 140 may be smaller than that of thesubstrate 110. The protection layer 140 may be disposed in a regionexcluding an end of the substrate, and may include a plurality of openregions.

The protection layer 140 may include a first open region OA1 having ashape like a hole. The first open region OA1 may be a non-disposingregion of the protection layer 140 for electrically connecting thewiring pattern layer 120 and/or the plating layer 130 to the first chipC1.

The protection layer 140 may include a second open region OA2 having ashape like a hole. The second open region OA2 may be a non-disposingregion of the protection layer 140 for electrically connecting thewiring pattern layer 120 and/or the plating layer 130 to the second chipC2. Accordingly, the plating layer 130 may be exposed to the outside inthe second open region OA2.

In the second open region OA2, a copper content of the plating layer 130may be 50 atomic % or more. For example, the copper content in theplating layer 130 may be 60 atomic % or more. For example, the coppercontent in the plating layer 130 may be 60 atomic % to 80 atomic %.Specifically, a copper content of the first plating layer 131 measuredin the second open region OA2 may be 60 atomic % to 80 atomic %.

The protection layer 140 may not be disposed on the conductive patternpart for being electrically connected to the main board 40 or thedisplay panel 30. The embodiment may include a third open region OA3that is a non-disposing region of the protection layer 140 on theconductive pattern part to be electrically connected to the main board40 or the display panel 30. Accordingly, the plating layer 130 may beexposed to the outside in the third open region OA3.

In the third open region OA3, a copper content of the plating layer 130may be 50 atomic % or more. Alternatively, in the third open region OA3,a copper content of the plating layer 130 may be less than 50 atomic %.The third open region OA3 may be positioned outside the substrate ascompared with the first open region OA1. In addition, the third openregion OA3 may be positioned outside the substrate as compared with thesecond open region OA2.

The first open region OA1 and the second open region OA2 may bepositioned in a central region of the substrate as compared with thethird open region OA3.

The protection layer 140 may be disposed in a bending region.Accordingly, the protection layer 140 may disperse stress that may occurduring bending. Therefore, reliability of the flexible circuit board forall-in-one chip on film according to the embodiment may be improved.

The protection layer 140 may include an insulating material. Theprotection layer 140 may include various materials that may be heatedand cured after being applied to protect the surface of the conductivepattern part. The protection layer 140 may be a resist layer. Forexample, the protection layer 140 may be a solder resist layer includingan organic polymer material. For example, the protection layer 140 mayinclude an epoxy acrylate resin. In detail, the protection layer 140 mayinclude a resin, a curing agent, a photo initiator, a pigment, asolvent, a filler, an additive, an acrylic monomer, and the like.However, the embodiment is not limited thereto, and it is needless tosay that the protection layer 140 may be any one of a photo-solderresist layer, a cover-lay, and a polymer material.

The protection layer 140 may have a thickness of 1 μm to 20 μm. Theprotection layer 140 may have a thickness of 1 μm to 15 μm. For example,the protection layer 140 may have a thickness of 5 μm to 20 μm. When thethickness of the protection layer 140 exceeds 20 μm, the thickness ofthe flexible circuit board for all-in-one chip on film may increase.When the thickness of the protection layer 140 is less than 1 μm,reliability of the conductive pattern part included in the flexiblecircuit board for all-in-one chip on film may be lowered.

In other words, a single-side flexible circuit board 100 for all-in-onechip on film according to an embodiment may include a substrate 110, aconductive pattern part CP disposed on one surface of the substrate,dummy pattern parts DP1 and DP2, and a protective part PP formed bypartially disposing a protection layer 140 in one region on the dummypattern parts DP1 and DP2 and the conductive pattern part CP.

The conductive pattern part CP may include the wiring pattern layer 120and the plating layer 130.

The protective part PP may not be disposed on one region and anotherregion on the conductive pattern part CP.

In addition, the protective part PP may be disposed on the dummy patternparts DP1 and DP2.

Accordingly, the conductive pattern part CP and the substrate 110between the separated conductive pattern parts CP may be exposed on theone region and the other region on the conductive pattern part CP. Afirst connection part 70 and a second connection part 80 may be disposedon the one region and the other region on the conductive pattern partCP, respectively. Specifically, the first connection part 70 and thesecond connection part 80 may be disposed on an upper surface of theconductive pattern part CP in which the protective part PP is notdisposed, respectively.

The first connection part 70 and the second connection part 80 may havedifferent shapes. For example, the first connection part 70 may be ahexahedral shape. Specifically, a cross-section of the first connectionpart 70 may include a quadrangular shape. In more detail, thecross-section of the first connection part 70 may include a rectangularor square shape. For example, the second connection part 80 may includea spherical shape. A cross-section of the second connection part 80 mayinclude a circular shape. Alternatively, the second connection part 80may include a partially or wholly rounded shape. As an example, thecross-sectional shape of the second connection part 80 may include aflat surface on one side surface and a curved surface on the other sidesurface opposite to the one side surface.

The first connection part 70 and the second connection part 80 may havedifferent sizes. The first connection part 70 may be smaller than thesecond connection part 80.

Widths of the first connection part 70 and the second connection part 80may be different from each other. For example, a width D1 between bothside surfaces of one first connection part 70 may be smaller than awidth D2 between both side surfaces of one second connection part 80.

The first chip C1 may be disposed on the first connection part 70. Thefirst connection part 70 may include a conductive material. Accordingly,the first connection part 70 may electrically connect the first chip C1disposed on an upper surface of the first connection part 70 and theconductive pattern part CP disposed on a lower surface of the firstconnection part 70.

The second chip C2 may be disposed on the second connection part 80. Thesecond connection part 80 may include a conductive material.Accordingly, the second connection part 80 may electrically connect thesecond chip C2 disposed on an upper surface of the second connectionpart 80 and the conductive pattern part CP disposed on a lower surfaceof the second connection part 80.

Different types of first and second chips C1 and C2 may be disposed onthe same one surface of the single-side flexible circuit board 100 forall-in-one chip on film according to the embodiment. Specifically, onefirst chip C1 and a plurality of second chips C2 may be disposed on thesame one surface of the single-side flexible circuit board 100 forall-in-one chip on film according to the embodiment. Accordingly,efficiency of a chip packaging process may be improved.

The first chip C1 may include a drive IC chip.

The second chip C2 may refer to a chip other than a drive IC chip. Thesecond chip C2 may refer to various chips including a socket or anelement other than a drive IC chip. For example, the second chip C2 mayinclude at least one of a diode chip, a power supply IC chip, a touchsensor IC chip, a multilayer ceramic capacitor (MLCC) chip, a ball gridarray (BGA) chip, and a chip condenser.

The plurality of second chips C2 disposed on the flexible circuit board100 for all-in-one chip on film may refer to at least one of a diodechip, a power supply IC chip, a touch sensor IC chip, an MLCC chip, aBGA chip, and a chip condenser disposed in plural. As an example, aplurality of MLCC chips may be disposed on the flexible circuit board100 for all-in-one chip on film.

In addition, the second chip C2 may include at least two of the diodechip, the power supply IC chip, the touch sensor IC chip, the MLCC chip,the BGA chip, and the chip condenser. That is, a plurality of differenttypes of second chips C2A and C2B may be disposed on the flexiblecircuit board 100 for all-in-one chip on film. For example, the secondchip C2A of any one of the diode chip, the power supply IC chip, thetouch sensor IC chip, the MLCC chip, the BGA chip, and the chipcondenser and one second chip C2B different from the any one of thediode chip, the power supply IC chip, the touch sensor IC chip, the MLCCchip, the BGA chip, and the chip condenser may be included on theflexible circuit board 100 for all-in-one chip on film.

Specifically, the second chip C2A of any one of the diode chip, thepower supply IC chip, the touch sensor IC chip, the MLCC chip, the BGAchip, and the chip condenser may be disposed on the flexible circuitboard 100 for all-in-one chip on film in plural, and the second chip C2Bdifferent from the any one of the diode chip, the power supply IC chip,the touch sensor IC chip, the MLCC chip, the BGA chip, and the chipcondenser may be disposed thereon in plural. As an example, a pluralityof MLCC chips C2A and a plurality of power supply IC chips C2B may beincluded on the flexible circuit board 100 for all-in-one chip on film.As an example, the plurality of MLCC chips C2A and a plurality of diodechips C2B may be included on the flexible circuit board 100 forall-in-one chip on film. As an example, the plurality of MLCC chips C2Aand a plurality of BGA chips C2B may be included on the flexible circuitboard 100 for all-in-one chip on film.

In the embodiment, a type of the second chip is not limited to two, andit is needless to say that all the various chips excluding the drive ICchip may be included in the second chip.

One end of the flexible circuit board 100 for all-in-one chip on filmmay be connected to a display panel 30. One end of the flexible circuitboard 100 for all-in-one chip on film may be connected to the displaypanel 30 by an adhesive layer 50. Specifically, the display panel 30 maybe disposed on an upper surface of the adhesive layer 50, and theflexible circuit board 100 for all-in-one chip on film may be disposedon a lower surface of the adhesive layer 50. Accordingly, the displaypanel 30 and the flexible circuit board 100 for all-in-one chip on filmmay be bonded vertically with the adhesive layer 50 interposedtherebetween.

The other end opposite to the one end of the flexible circuit board 100for all-in-one chip on film may be connected to a main board 40. Theother end opposite to the one end of the flexible circuit board 100 forall-in-one chip on film may be connected to the main board 40 by anadhesive layer 50. Specifically, the main board 40 may be disposed onthe upper surface of the adhesive layer 50, and the flexible circuitboard 100 for all-in-one chip on film may be disposed on the lowersurface of the adhesive layer 50. Accordingly, the main board 40 and theflexible circuit board 100 for all-in-one chip on film may be bondedvertically with the adhesive layer 50 interposed therebetween.

The adhesive layer 50 may include a conductive material. The adhesivelayer 50 may be formed by dispersing conductive particles in an adhesivematerial. For example, the adhesive layer 50 may be an anisotropicconductive film (ACF).

Accordingly, the adhesive layer 50 may transmit electrical signalsbetween the display panel 30, the flexible circuit board 100 forall-in-one chip on film, and the main board 40, and may stably connectother components.

Meanwhile, the dummy pattern parts DP1 and DP2 as described above aredisposed on the substrate 110. That is, the upper dummy pattern part DP2is disposed on the upper surface of the substrate 110, and the lowerdummy pattern part DP1 is disposed on the lower surface of the substrate110.

The upper dummy pattern part DP2 may be disposed in a region of theupper surface of the substrate 110, in which the upper wiring patternlayer is not disposed. Preferably, the upper dummy pattern part DP2 maybe disposed in a region of the upper surface of the substrate overlappedvertically with the lower wiring pattern layer disposed at the lowersurface of the substrate 110, in which the upper wiring pattern layer isnot disposed.

The lower dummy pattern part DP1 may be disposed in a region of thelower surface of the substrate 110, in which the lower wiring patternlayer is not disposed. Preferably, the lower dummy pattern part DP1 maybe disposed in a region of the lower surface of the substrate overlappedvertically with the upper wiring pattern layer disposed at the uppersurface of the substrate 110, in which the upper wiring pattern layer isnot disposed.

That is, positions of the upper wiring pattern layer and the lowerwiring pattern layer disposed on the substrate 110 do not correspond toeach other, and are designed according to a function of each and thenumber of signal wiring lines, and are disposed on each surface of thesubstrate 110.

Therefore, the lower wiring pattern layer and the lower plating layermay not be disposed at the lower surface of the substrate 110 overlappedvertically with the region in which the upper wiring pattern layer andthe upper plating layer are disposed. In addition, the upper wiringpattern layer and the upper plating layer may not be disposed at theupper surface of the substrate 110 overlapped vertically with a regionin which the lower wiring pattern layer and the lower plating layer aredisposed.

At this time, the protection layer 140 is disposed on the substrate 110by a printing process. The protection layer 140 is preferentiallyprinted on one surface of the substrate 110, and after the printingprocess on the one surface is completed, a printing process of the othersurface of the substrate 110 is performed.

Here, in a surface on which the protection layer 140 is printed first ofthe one surface and the other surface of the substrate, a region inwhich a wiring pattern layer/a plating layer is not disposed and aregion in which the wiring pattern layer/the plating layer is disposedcoexist at an opposite surface thereof, and thus a step occurs. At thistime, when the step is present on a surface opposite to a surface onwhich the protection layer 140 is printed, a problem that the protectionlayer 140 is not disposed in the printing process of the protectionlayer 140 or a problem of pin-holes may occur, which will greatly affectthe reliability of the printed circuit board.

Therefore, in the present invention, in order to solve the aboveproblems, the dummy pattern parts DP1 and DP2 are formed on the oppositesurface of the surface on which the protection layer 140 is printed sothat the step does not exist.

At this time, when the printing process of the protection layer 140 ispreferentially performed on the upper surface of both surfaces of thesubstrate 110, the dummy pattern parts DP1 and DP2 may include only thelower dummy pattern part DP1. That is, when the protection layer 140 isprinted at the upper surface of the substrate 110, a pattern step issolved by the lower dummy pattern part DP1 disposed on the lower surfaceof the substrate 110, and accordingly, the protection layer 140 having auniform height may be disposed on the upper surface of the substrate110.

Then, when the printing process of the protection layer 140 for thelower surface of the substrate 110 is performed after the printingprocess of the protection layer 140 for the upper surface of thesubstrate 110 is completed, a step between the protection layer 140formed on the upper surface of the substrate 110 and the upper wiringpattern layer/the upper plating layer is solved, and accordingly, auniform protection layer 140 may be formed at the lower surface of thesubstrate 110.

However, of the one surface and the other surface of the substrate 110,the surface on which the protection layer 140 is printed first,frequently changes according to a manufacturing environment of theprinted circuit board. Therefore, in the present invention, consideringthe manufacturing environment of the printed circuit board as describedabove, the upper dummy pattern part DP2 is formed at a positioncorresponding to the lower wiring pattern layer and the lower platinglayer of the upper surface of the substrate 110, and the lower dummypattern part DP1 is formed at a position corresponding to the upperwiring pattern layer and the upper plating layer of the lower surface ofthe substrate 110. Here, the corresponding position refers to a positionon the other surface of the substrate overlapped vertically with thewiring pattern layer and the plating layer disposed on one surface ofthe substrate 110.

The dummy pattern parts DP1 and DP2 may be formed of a single layer.Preferably, the dummy pattern parts DP1 and DP2 may include only a dummypattern layer. The dummy pattern layer may include the same metalmaterial as that of the wiring pattern layer. However, the presentinvention is not limited thereto, and the dummy pattern layer mayinclude a different material from that of the wiring pattern layer. Forexample, the dummy pattern layer may include a non-metallic material.

In addition, alternatively, as shown in FIG. 3B, the dummy pattern partsDP1 and DP2 may include a first dummy pattern layer 151, a second dummypattern layer 152, and a third dummy pattern layer 153.

The first dummy pattern layer 151 corresponds to the wiring patternlayer 120. The first dummy pattern layer 151 includes the same metalmaterial as that of the wiring pattern layer 120. The first dummypattern layer 151 may be a part of the wiring pattern layer 120. Inother words, the wiring pattern layer 120 electrically connected to achip and transmitting signals is disposed at the surface of thesubstrate 110. In this case, the first dummy pattern layer 151 may beformed together with the wiring pattern layer 120. That is, a patternlayer is formed on the substrate 110, which includes the wiring patternlayer 120 for transmitting an electrical signal and the first dummypattern layer 151. The first dummy pattern layer 151 does not transmitan electrical signal unlike the wiring pattern layer 120, andaccordingly, is not electrically connected to the wiring pattern layer120. That is, the first dummy pattern layer 151 may not be connected tothe wiring pattern layer 120, and may be independently disposed on aregion in which the wiring pattern layer 120 is not disposed of thesurface of the substrate 110.

The second dummy pattern layer 152 is disposed on the first dummypattern layer 151. The second dummy pattern layer 152 may be a part ofthe first plating layer 131. The third dummy pattern layer 152 isdisposed on the second dummy pattern layer 152. The third dummy patternlayer 153 may be a part of the second plating layer 132.

In other words, the dummy pattern parts DP1 and DP2 in the presentinvention may be formed as a single layer, unlike a layer structure ofthe conductive pattern part CP. In addition, the dummy pattern parts DP1and DP2 may be formed of three layers, like the layer structure of theconductive pattern part CP.

Meanwhile, the protection layer 140 is disposed on the dummy patternparts DP1 and DP2. That is, the protection layer 140 exposes a part of asurface of the conductive pattern part CP to be opened. In addition, thedummy pattern parts DP1 and DP2 need not be exposed to the outside, andaccordingly, the protection layer 140 is disposed on the dummy patternparts DP1 and DP2.

Meanwhile, referring to FIG. 3A, the area of the wiring pattern layer120 may correspond to the plating layer 130. The area of the firstplating layer 131 may correspond to the area of the second plating layer132.

Referring to FIG. 7 , the area of the wiring pattern layer 120 may bedifferent from that of the plating layer 130. The area of the wiringpattern layer 120 may correspond to the area of the first plating layer131. The area of the first plating layer 131 may be different from thatof the second plating layer 132. For example, the area of the firstplating layer 131 may be larger than that of the second plating layer132.

Referring to FIG. 8 , the area of the wiring pattern layer 120 may bedifferent from that of the plating layer 130.

Referring to FIG. 9 , the area of the wiring pattern layer 120 on onesurface of the substrate 110 is different from that of the plating layer130, and the area of the wiring pattern layer 120 on the other surfaceof the substrate 110 may correspond to the area of the plating layer.130.

The protection layer 140 may be disposed on the substrate 110 in directcontact, disposed on the wiring pattern layer 120 in direct contact, ordisposed on the first plating layer 131 in direct contact. or disposedon the second plating layer 132 in direct contact. In addition, theprotection layer 140 may be disposed in direct contact with the dummypattern parts DP1 and DP2.

Referring to FIGS. 3A and 3B, the first plating layer 131 may bedisposed on the wiring pattern layer 120, the second plating layer 132may be formed on the first plating layer 131, and the protection layer140 may be partially disposed on the second plating layer 132. Inaddition, the protection layer 140 may be entirely disposed on the dummypattern parts DP1 and DP2.

Referring to FIGS. 7A and 7B, the first plating layer 131 may bedisposed on the wiring pattern layer 120, and the protection layer 140may be partially disposed on the first plating layer 131. The secondplating layer 132 may be disposed in a region other than a region inwhich the protection layer 140 is disposed on the plating layer 131.

The first plating layer 131 in contact with a lower surface of theprotection layer 140 may be an alloy layer of copper and tin. The secondplating layer 132 contacting a side surface of the protection layer 140may include pure tin. Accordingly, formation of a cavity part betweenthe protection layer 140 and the first plating layer 131 may prevent theprotection layer from being removed and prevent formation of whiskers,thereby increasing adhesion of the protection layer. Therefore, theembodiment may include two layers of plating layers, and thus anelectronic device with high reliability may be provided.

In addition, when only the single-layered tin plating layer 131 isdisposed on the wiring pattern layer 120, and when the protection layer140 is disposed on one tin plating layer 131, the tin plating layer 131is heated when the protection layer 140 is thermally cured, and thuscopper may diffuse into the tin plating layer 131. Accordingly, sincethe tin plating layer 131 may be an alloy layer of tin and copper, thereis a problem that the first chip having a gold bump may be not firmlymounted. Therefore, the plating layer 130 according to the embodimentrequires the first plating layer 131 and the second plating layer 132that may continuously increase a tin concentration as a distance fromthe substrate increases.

In addition, as shown in FIG. 7A, the dummy pattern parts DP1 and DP2may include a single dummy pattern layer corresponding to the wiringpattern layer 120 and the first plating layer 131.

Further, as shown in FIG. 7B, the dummy pattern parts DP1 and DP2 mayinclude a first dummy pattern layer 151 corresponding to the wiringpattern layer 120, a second dummy pattern layer 152 corresponding to thefirst plating layer 131, and a third dummy pattern layer 153corresponding to the second plating layer 132.

Referring to FIG. 8 , the first plating layer 131 may be disposed on thewiring pattern layer 120, and the protection layer 140 may be partiallydisposed on the first plating layer 131. The second plating layer 132may be disposed in a region other than the region in which theprotection layer 140 is disposed on the plating layer 131.

At this time, the wiring pattern layer 120 may include a first wiringpattern layer 121 and a second wiring pattern layer 122. That is, aplurality of wiring pattern layers may be disposed on the substrate.

In addition, although not shown in drawings, a metal seed layer forimproving adhesion between the substrate 110 and the first wiringpattern layer 121 may be further included between the substrate 110 andthe first wiring pattern layer 121. At this time, the metal seed layermay be formed by sputtering. The metal seed layer may include copper.

The first wiring pattern layer 121 and the second wiring pattern layer122 may correspond to each other, or may be formed in differentprocesses.

The first wiring pattern layer 121 may be formed by sputtering copper ina thickness of 0.1 μm to 0.5 μm. The first wiring pattern layer 121 maybe disposed at upper and lower portions of the substrate and an innerside surface of the through-hole. At this time, since the first wiringpattern layer 121 is thin, the inner side surface of the through-holemay be spaced apart from each other.

Next, the second wiring pattern layer 122 may be disposed on the firstwiring pattern layer 121. In addition, the second wiring pattern layer122 may be entirely filled in the through-hole by plating.

Since the first wiring pattern layer 121 is formed by sputtering, thefirst wiring pattern layer 121 has an advantage of excellent adhesion tothe substrate 110 or the metal seed layer, but a manufacturing cost ishigh, and thus the manufacturing cost may be reduced by forming againthe second wiring pattern layer 122 on the first wiring pattern layer121 by plating. In addition, the second wiring pattern layer 122 may bedisposed on the first wiring pattern layer 121 and at the same time, thevia hole may be filled with copper without separately filling thethrough-hole of the substrate with a conductive material, therebyimproving process efficiency. Further, since it is possible to preventvoids from being formed in the via hole, a highly reliable flexiblecircuit board for all-in-one chip on film and an electronic deviceincluding the same may be provided.

In addition, dummy pattern parts DP1 and DP2 may include a first dummypattern layer 151 corresponding to the first wiring pattern layer 121, asecond dummy pattern layer 152 corresponding to the second wiringpattern layer 122, a third dummy pattern layer 153 corresponding to thefirst plating layer 131, and a fourth dummy pattern layer 154corresponding to the second plating layer 132.

Referring to FIG. 9 , a plurality of protection layers 140 may bedisposed on one surface of the substrate. The protection layer mayinclude a first protection layer 141 and a second protection layer 142.

For example, the first protection layer 141 may be partially disposed onone surface of the substrate, and the wiring pattern layer 120 may bedisposed on a region other than the region in which the protection layer141 is disposed.

The second protection layer 142 may be disposed on the protection layer141. The second protection layer 142 may cover the first protectionlayer 141 and the wiring pattern layer 120, and may be disposed in alarger region than the first protection layer 141.

The protection layer 142 may be disposed on a region corresponding tothe protection layer 141 while surrounding an upper surface of the firstprotection layer 141. A width of the second protection layer 142 may belarger than that of the protection layer 141. Accordingly, a lowersurface of the second protection layer 142 may be in contact with thewiring pattern layer 120 and the first protection layer 141.Accordingly, the second protection layer 142 may relieve stressconcentration at an interface between the first protection layer 141 andthe wiring pattern layer 120. Therefore, when bending the flexiblecircuit board for all-in-one chip on film according to the embodiment,it is possible to reduce an occurrence of removal of a film or cracks.

The plating layer 130 may be disposed in a region other than the regionin which the second protection layer 142 is disposed. Specifically, thefirst plating layer 131 may be disposed on the wiring pattern layer 120in a region other than the region in which the second protection layer142 is disposed, and the second plating layer 132 may be disposed on thefirst plating layer 131 in order.

The wiring pattern layer 120 may be disposed on the other surfaceopposite to the one surface of the substrate. The plating layer 130 maybe disposed on the wiring pattern layer 120. The protection layer 140may be partially disposed on the plating layer 130.

Widths of the protection layer disposed on one surface of the substrateand the protection layer disposed on the other surface of the substratemay correspond to each other or may be different from each other.

In the drawing, it is shown that a plurality of protection layers aredisposed only on one surface of the substrate, but the embodiment is notlimited thereto, and it is needless to say that the plurality ofprotection layers may be included on both surfaces of the substrate. Inaddition, it is needless to say that a plurality of or one protectionlayer may be disposed only on one surface of the substrate.

In addition, it is needless to say that a structure of one surface orboth surfaces of the substrate may be variously disposed by combiningstructures of the conductive pattern part and the protective partaccording to at least one of FIGS. 3A, 3B, 7A, 7B, 8 and 9 .

Referring to FIGS. 4A and 4B, in a flexible circuit board according to acomparative example, an upper conductive pattern part CP is disposed onan upper surface of a substrate 110, and a lower conductive pattern partCP is disposed on a lower surface of the substrate 110. At this time,the upper conductive pattern part CP and the lower conductive patternpart CP are designed without considering a printing process of aprotection layer 140. Therefore, the upper conductive pattern part CPmay be present on the upper surface of the substrate 110, but a regionin which the lower conductive pattern part CP does not exist may beincluded at the lower surface of the substrate 110. In other words, aregion in which the lower conductive pattern part CP is not disposed ispresent on the lower surface of the substrate 110 overlapped verticallywith a surface on which the upper conductive pattern part CP isdisposed.

In this case, in the flexible circuit board according to the comparativeexample, the lowermost surface becomes the lower surface of the lowerconductive pattern part CP in the region in which the lower conductivepattern part CP exists, and the lowermost surface becomes the lowersurface of the substrate 110 in the region in which the lower conductivepattern part CP does not exist.

In addition, in a process of printing the protection layer 140 on theupper surface of the substrate 110, the lowermost surface is the same asthe lower surface of the substrate 110 in the region overlappedvertically with the region in which the lower conductive pattern part CPis not disposed, and accordingly, a pinhole phenomenon does not occur.In this case, in a state of printing the protection layer 140 in theregion in which the lower conductive pattern part CP does not exist,when the lower conductive pattern part CP suddenly appears, a spatteringphenomenon occurs due to a sudden occurrence of a step in an upperregion of the substrate 110 overlapped vertically with an end of thelower conductive pattern part CP. Accordingly, in the related art, thespattering phenomenon occurs in an end region in which the lower dummypattern part DP1 is first disposed, and accordingly, a pinhole problemin which the protection layer 140 is not disposed occurs.

Meanwhile, as shown in FIG. 4B, in the present invention, the lowerdummy pattern part DP1 is disposed at the lower surface of the substrate110 overlapped vertically with the region in which the upper conductivepattern part CP is disposed, and thus the occurrence of the step may beeliminated, and accordingly, a uniform protection layer 140 may beformed.

In addition, the lower dummy pattern part DP1 may be disposed tocorrespond to each of the upper conductive pattern parts CP. In otherwords, as shown in FIG. 4B, it may be confirmed that three upperconductive pattern parts CP are disposed on the upper surface of thesubstrate 110 overlapped vertically with the region in which the lowerconductive pattern part CP is not disposed. Accordingly, a first lowerdummy pattern part DP1, a second lower dummy pattern part DP1, and athird lower dummy pattern part DP1 may be disposed respectively at thelower surface of the substrate 110 to correspond to each of the threeupper conductive pattern parts CP.

Meanwhile, the pinhole phenomenon of the protection layer 140 asdescribed above is because a position at which a first upper conductivepattern part CP on the upper surface of the substrate 110 on which theprotection layer 140 is printed is started and a position at which afirst lower conductive pattern part CP on the lower surface of thesubstrate is started are different from each other. Preferably, theposition at which the lower conductive pattern part CP is started isfarther than the position at which the first upper conductive patternpart CP is started based on a left end of the substrate.

Therefore, the pinhole phenomenon may be solved by setting the positionat which the first upper conductive pattern part CP is started to be thesame as the position at which the lower conductive pattern part CP isstarted.

That is, as shown in FIG. 5A, when the region A of FIG. 3A is enlarged,it may be confirmed that four upper conductive pattern parts CP aredisposed on the upper surface of the substrate 110 with respect to theleft end. In addition, it may be confirmed that two lower conductivepattern parts CP are disposed on the lower surface of the substrate 110with respect to the left end. That is, it may be confirmed that thelower conductive pattern part CP is started initially at the position ofthe upper conductive pattern part CP positioned third of the four upperconductive pattern parts CP.

Therefore, in the present invention, the lower dummy pattern part DP1 isdisposed on a region overlapped vertically with the first upperconductive pattern part CP of the lower surface of the substrate 110. Atthis time, the left end of the first upper conductive pattern part andthe left end of the lower dummy pattern part DP1 may be positioned onthe same vertical line. That is, a starting position of the first upperconductive pattern part CP and a starting position of the lower dummypattern part DP1 are set the same on the upper and lower surfaces of thesubstrate 110. In addition, the lower conductive pattern part CP or thelower dummy pattern part DP1 may not be disposed on a region overlappedvertically with the second upper conductive pattern part CP.

That is, when the lower conductive pattern part CP is not disposed onthe lower surface of the substrate 110 overlapped with the startingposition of the first upper conductive pattern part CP, the lower dummypattern part DP1 may be disposed only on the lower surface of thesubstrate 110 overlapped with the starting position of the first upperconductive pattern part CP to solve the pinhole phenomenon.

However, in order to completely solve the pinhole phenomenon using theone lower dummy pattern part DP1, it is preferable that a width of thelower dummy pattern part DP1 is set larger than that of the first upperconductive pattern part CP.

Alternatively, as shown in FIG. 5B, the lower dummy pattern part DP1 isdisposed on the region overlapped vertically with the first upperconductive pattern part CP of the lower surface of the substrate 110. Atthis time, the left end of the first upper conductive pattern part andthe left end of the lower dummy pattern part DP1 may not be positionedon the same vertical line. That is, the starting position of the firstupper conductive pattern part CP and the starting position of the lowerdummy pattern part DP1 may not be the same on the upper and lowersurfaces of the substrate 110. At this time, under the above conditions,in order to solve the pinhole phenomenon, a starting position of apattern initially disposed on the opposite surface of the surface to beprinted should be faster than a starting position of a pattern initiallydisposed on the surface on which the protection layer 140 is printed(including the conductive pattern part CP and the dummy pattern partsDP1 and DP2).

Therefore, in the present invention, the lower dummy pattern part DP1 isformed on the lower surface of the substrate 110 overlapped verticallywith the first upper conductive pattern part CP such that the startingposition of the lower dummy pattern part DP1 disposed on the lowersurface of the substrate 110 is faster than the starting position of thefirst upper conductive pattern part CP.

In other words, a distance from the left end of the substrate 110 to theleft end of the lower dummy pattern part DP1 is set closer than adistance from the left end of the substrate 110 to the left end of thefirst upper conductive pattern part CP.

In conclusion, there may be a difference of about a first pitch a fromthe left end of the first upper conductive pattern part CP to the leftend of the lower dummy pattern part DP1. In addition, the width of thefirst upper conductive pattern part CP has a first width b, and thewidth of the lower dummy pattern part DP1 is set to have a second widthc wider than the first width b.

Accordingly, in the present invention, the pinhole phenomenon may besolved by forming a minimum number of dummy pattern parts.

In addition, as shown in FIG. 5C, the lower dummy pattern part DP1 mayhave a third width d. At this time, the third width d may correspond tothe total width of a width of the first upper conductive pattern partCP, a width of the second upper conductive pattern part CP, and aspacing width between the first upper conductive pattern part CP and thesecond upper conductive pattern part CP.

In other words, in FIG. 4B, the first lower dummy pattern part DP1having the same width as the first upper conductive pattern part CP wasformed under the first upper conductive pattern part CP, and the secondlower dummy pattern part DP1 having the same width as the second upperconductive pattern part CP was formed under the second upper conductivepattern part CP.

Alternatively, as shown in FIG. 5C, only one conductive pattern part CPmay be formed on the lower surface of the substrate 110 corresponding toan end position of the second upper conductive pattern part CP from thestarting position of the first upper conductive pattern part CP.

Meanwhile, the dummy pattern parts DP1 and DP2 in the present inventionmay have various shapes. That is, since the dummy pattern parts DP1 andDP2 are disposed to eliminate a step at a lower portion of the printedsurface of the protection layer 140, a thickness of the pattern partshould be maintained to be the same as that of the conductive patternpart CP. Accordingly, the dummy pattern parts DP1 and DP2 may have a barshape extending horizontally as shown in (a) of FIG. 5D, may have a barshape extending vertically as shown in (b), may have a circular shape asshown in (c), may have a circular shape (ring shape) with an open centeras shown in (d), and may have a quadrangular shape (ladder shape) withan open center as shown in (e). In addition, the shape of the dummypattern parts DP1 and DP2 in the present invention is not limitedthereto, and may be modified into various shapes such as an ellipticalshape, a fan shape, a polygonal shape, and a triangular shape.

In addition, as shown in FIG. 6 , when region B of FIG. 3A is enlarged,the upper dummy pattern part DP2 is disposed on the upper surface of thesubstrate 110. A position and condition of forming the upper dummypattern part DP2 are the same as position and condition of forming thelower dummy pattern part DP1. That is, when the starting position of theupper conductive pattern part CP is later than the starting position ofthe lower conductive pattern part CP initially positioned, with respectto a right end of the substrate 110, the upper dummy pattern part DP2 isformed on the upper surface of the substrate 110 overlapped verticallywith the starting position of the lower conductive pattern part CPpositioned initially. At this time, the upper dummy pattern part DP2 maybe disposed in plural to correspond to the respective lower conductivepattern part CP, and alternatively, the upper dummy pattern part DP2 maybe formed in a single part only to correspond to the lower conductivepattern part CP started initially.

Referring to FIGS. 3A, 3B, 7A, 7B, 8, 10, and 11 , connectionrelationship of the first chip C1, the display panel 30, and the mainboard 40 mounted on the double-side flexible circuit board 100 forall-in-one chip on film will be described.

The double-side flexible circuit board 100 for all-in-one chip on filmaccording to the embodiment may include: a substrate 100 including athrough-hole; a wiring pattern layer 120 disposed on both surfaces ofthe substrate including the through-hole; a first plating layer 131disposed on the wiring pattern layer 120; a second plating layer 132disposed on the first plating layer 131; and a protection layer 140partially disposed on the wiring pattern layer.

A disposing region of the protection layer 400 in which the protectionlayer 140 is formed may be the protective part PP. The conductivepattern part CP may be exposed to the outside in a region other than theprotective portion PP in which the protection layer 140 is not formed.That is, the conductive pattern part CP may be electrically connected tothe first chip C1, the display panel 30, and the main board 40 in anopen region of the protection layer or a region in which the protectivepart is not disposed on the conductive pattern part.

A lead pattern part and a test pattern part of the flexible circuitboard for all-in-one chip on film according to the embodiment may notoverlap with the protective part. That is, the lead pattern part and thetest pattern part may refer to a conductive pattern part positioned inan open region that is not covered by a protection layer, and may bedistinguished into a lead pattern part and a test pattern part accordingto functions.

The lead pattern part may refer to a conductive pattern part to beconnected to the first chip, the second chip, the display panel, or themain board.

The test pattern part may refer to a conductive pattern part forchecking whether the flexible circuit board for all-in-one chip on filmaccording to the embodiment and a product of a chip package includingthe same is defective.

The lead pattern part may be distinguished into an inner lead patternpart and an outer lead pattern part depending on a location. One regionof a conductive pattern part that is relatively close to the first chipC1 and is not overlapped by a protection layer may be represented as theinner lead pattern part. One region of a conductive pattern part that ispositioned relatively far from the first chip C1 and is not overlappedby a protection layer may be represented as the outer lead pattern part.

Referring to FIGS. 3A, 3B, 7A, 7B, 8, 10, and 11 , a flexible circuitboard 100 for all-in-one chip on film according to the embodiment mayinclude a first inner lead pattern part I1, a second inner lead patternpart I2, a third inner lead pattern part I3, and a fourth inner leadpattern part I4.

The flexible circuit board 100 for all-in-one chip on film according tothe embodiment may include a first outer lead pattern part O1, a secondouter lead pattern part O2, a third outer lead pattern part O3, and afourth outer lead pattern part O4.

The flexible circuit board 100 for all-in-one chip on film according tothe embodiment may include a first test pattern part T1 and a secondtest pattern part T2.

The first inner lead pattern part I1, the second inner lead pattern partI2, the third inner lead pattern part I3, the first outer lead patternpart O1, and the second outer lead pattern part O2 may be disposed onone surface of the flexible circuit board 100 for all-in-one chip onfilm according to the embodiment.

The fourth inner lead pattern part I4, the third outer lead pattern partO3, the fourth outer lead pattern part O4, the first test pattern partT1, and the second test pattern part T2 may be included on the othersurface opposite to the one surface of the flexible circuit board 100for all-in-one chip on film according to the embodiment

The first chip C1 disposed on one surface of the flexible circuit board100 for all-in-one chip on film according to the embodiment may beconnected to the first inner lead pattern part I1, the second inner leadpattern part I2, or the third inner lead pattern part I3 via a firstconnection part 70.

The first connection part 70 may include a first sub second connectingpart 71, a second sub first connection part 72, and a third sub firstconnection part 73 depending on the location and/or function.

The first chip C1 disposed on one surface of the flexible circuit board100 for all-in-one chip on film according to the embodiment may beelectrically connected to the first inner lead pattern part I1 via thefirst sub first connection part 71.

The first inner lead pattern part I1 may transmit an electrical signalto the first outer lead pattern part O1 adjacent to a second via hole V2along the upper surface of the substrate 110. The second via hole V2 andthe first outer lead pattern part O1 may be electrically connected toeach other. That is, the first inner lead pattern part I1 and the firstouter lead pattern part O1 may be one end and the other end of theconductive pattern part extending in one direction.

For example, the main board 40 may be connected to the first outer leadpattern part O1 via an adhesive layer 50. Accordingly, a signaltransmitted from the first chip may be transmitted to the main board 40via the first inner lead pattern part I1 and the first outer leadpattern part O1

In addition, the first inner lead pattern part I1 may be electricallyconnected to the second via hole V2 along the upper surface of thesubstrate 110, and an electrical signal may be transmitted to the thirdouter lead pattern part O3 adjacent to the second via hole V2 along thelower surface of the substrate 110 through the conductive materialfilled in the second via hole V2. The second via hole V2 may beelectrically connected to the third outer lead pattern part O3.Accordingly, although not shown in the drawing, the main board 40 may beelectrically connected to the third outer lead pattern part O3 via theadhesive layer 50.

The first chip C1 disposed on one surface of the flexible circuit board100 for all-in-one chip on film according to the embodiment may beelectrically connected to the second inner lead pattern part I2 via thesecond sub first connection part 72.

The second inner lead pattern part I2 disposed on the upper surface ofthe substrate 110 may transmit an electrical signal to the fourth innerlead pattern part I4 and the first test pattern part T1 adjacent to afirst via hole V1 along the lower surface of the substrate 110 through aconductive material filled in the first via hole V1 positioned under thesecond inner lead pattern part I2. The first via hole V1, the first testpattern part T1, and the fourth inner lead pattern part I4 may beelectrically connected on the lower surface of the substrate.

The display panel 30 may be attached to the fourth inner lead patternpart I4 and the fourth outer lead pattern part O4.

The first test pattern part T1 may confirm a failure of an electricalsignal that may be transmitted through the first via hole V1. Forexample, accuracy of a signal transmitted to the fourth inner leadpattern part I4 may be confirmed via the first test pattern part T1. Indetail, by measuring a voltage or a current in the first test patternpart T1, it may be possible to confirm whether a short circuit or ashort occurs or a generated location of the short circuit or short inthe conductive pattern part positioned between the first chip and thedisplay panel, thereby improving reliability of a product.

The first chip C1 disposed on one surface of the flexible circuit board100 for all-in-one chip on film according to the embodiment may beelectrically connected to the third inner lead pattern part I3 via thethird sub first connection part 73.

The third inner lead pattern part I3 may transmit an electrical signalto the second outer lead pattern part O2 adjacent to a third via hole V3along the upper surface of the substrate 110. The third via hole V3 andthe second outer lead pattern part O2 may be electrically connected.That is, the third inner lead pattern part I3 and the second outer leadpattern part O2 may be one end and the other end of the conductivepattern part extending in one direction.

In addition, the third inner lead pattern part I3 may be electricallyconnected to the third via hole V3 along the upper surface of thesubstrate 110, and an electrical signal may be transmitted to the fourthouter lead pattern part O4 and the second test pattern part T2 adjacentto the third via hole V3 along the lower surface of the substrate 110through the conductive material filled in the third via hole V3.

The second via hole V2, the fourth outer lead pattern part O4, and thesecond test pattern part T2 may be electrically connected at the lowersurface of the substrate.

As described above, the display panel 30 may be attached to the fourthinner lead pattern part I4 and the fourth outer lead pattern part O4through the adhesive layer 50.

The second test pattern part T2 may confirm a failure of an electricalsignal that may be transmitted via the third via hole V3. For example,accuracy of a signal transmitted to the fourth outer lead pattern partO4 may be confirmed via the second test pattern part T2. In detail, bymeasuring a voltage or a current in the second test pattern part T2, itmay be possible to confirm whether a short circuit or a short occurs ora generated location of the short circuit or short in the conductivepattern part positioned between the first chip and the display panel,thereby improving reliability of a product.

The flexible circuit board for all-in-one chip on film according to theembodiment may dispose the display panel 30 on the other surfaceopposite to one surface on which the first chip C1 is disposed, therebyimproving the degree of freedom of design. Further, the display panel isdisposed on the other surface opposite to the one surface on which aplurality of chips are mounted, and thus it is possible to dissipateheat effectively. Accordingly, reliability of the flexible circuit boardfor all-in-one chip-on-film according to embodiment may be improved.

FIG. 10 is a plan view of FIG. 7A, and FIG. 11 is a bottom view of FIG.7A.

Referring to FIGS. 10 and 11 , the flexible circuit board 100 forall-in-one chip on film of the embodiment may include sprocket holes onboth outsides in the longitudinal direction for convenience ofmanufacturing or processing. Accordingly, the flexible circuit board 100for all-in-one chip on film of the embodiment may be rolled or unwoundby sprocket holes in a roll-to-roll method.

The flexible circuit board 100 for all-in-one chip on film of theembodiment may be defined as an inner region IR and an outer region ORbased on a cut portion indicated by a dotted line.

The conductive pattern part for connecting respectively the first chip,the second chip, the display panel, and the main board may be disposedin the inner region IR of the flexible circuit board 100 for all-in-onechip on film.

A chip package including the flexible circuit board 100 for all-in-onechip on film and an electronic device including the same may beprocessed by cutting a portion in which a sprocket hole is formed on theflexible circuit board 100 for all-in-one chip on film and disposing achip on a substrate.

Referring to FIG. 11 , on the upper surface of the flexible circuitboard 100 for all-in-one chip on film, the first inner lead pattern partI1, the second inner lead pattern part I2, and the third inner leadpattern part I3 which are one region of a conductive pattern part CP maybe exposed to the outside via a first open region OA1 of the protectionlayer 140.

In addition, on the upper surface of the flexible circuit board 100 forall-in-one chip on film, the first outer lead pattern part O1 which isone region of the conductive pattern part CP may be exposed to theoutside via a third open region OA3 of the protection layer 140.

The first inner lead pattern part I1 and the third inner lead patternpart I3 may be a conductive pattern part connected to a chip via a firstconnection part.

End portions of the first inner lead pattern part I1 and the third innerlead pattern part I3 may be disposed in the same row. For example, aplurality of the first inner lead pattern part I1 may be spaced apartfrom each other in a horizontal direction (x-axis direction) of asubstrate, and the end portions of the first inner lead pattern part I1may be disposed in the same row. For example, a plurality of the thirdinner lead pattern part I3 may be spaced apart from each other in ahorizontal direction (x-axis direction) of the substrate, and the endportions of the third inner lead pattern part I3 may be disposed in thesame row. Accordingly, the first inner lead pattern part I1 and thethird inner lead pattern part I3 may be excellent in bonding with thefirst connection part and the first chip.

A plurality of the second via holes V2 may be spaced apart from eachother in a horizontal direction (x-axis direction) of the substrate, andmay be disposed in the same row. A plurality of the third via holes V3may be spaced apart from each other in a horizontal direction (x-axisdirection) of the substrate, and may be disposed in the same row.

The end portion of the first inner lead pattern part I1 may be spacedapart from an end portion of a second inner lead pattern part I2.

The second inner lead pattern part I2 may be a conductive pattern thatis not bonded to the first chip. At least one end portion of one end andthe other end of the second inner lead pattern part I2 may not bedisposed in the same row.

For example, a plurality of the second inner lead pattern part I2 may bespaced from each other in a horizontal direction (x-axis direction) ofthe substrate. In addition, a separation distance between at least oneend portion of the one end and the other end of the second inner leadpattern part I2 and the end of the first inner lead pattern part I1 maydecrease as closer to the horizontal direction (x-axis direction) of thesubstrate. A separation distance between at least one end of the one endand the other end of the second inner lead pattern part I2 and the endof the first inner lead pattern part I1 may increase as closer to thehorizontal direction (x-axis direction) of the substrate.

A plurality of the first via holes V1 may be spaced apart from eachother and disposed in different rows in a horizontal direction (x-axisdirection) of the substrate.

A length between one end and the other end of the second inner leadpattern part I2 is gradually decreased as closer to the horizontaldirection (x-axis direction) of the substrate, and thus a first set partof the second inner lead pattern parts I2 may be included. In detail,the length between the one end and the other end of the second innerlead pattern part I2 is gradually decreased as closer to the horizontaldirection (x-axis direction) of the substrate from a first length to asecond length, and thus the first set part of the second inner leadpattern parts I2 having a second length may be included. At this time,the first length may be greater than the second length. A plurality offirst sets may be disposed on the substrate. Therefore, the second innerlead pattern part I2 having a length that is gradually decreased fromthe first length to the second length may be included on the substrate110. The second inner lead pattern part I2 adjacent to the second innerlead pattern part I2 having the second length may have the first lengthagain. Accordingly, the first set part of the second inner lead patternparts I2 of which length is gradually decreased from the first length tothe second length as closer to the horizontal (x-axis direction) of thesubstrate and the first set part of the second inner lead pattern partsI2 of which length is gradually decreased from the first length to thesecond length may be repeatedly disposed.

The separation distance between at least one end portion of the one endand the other end of the second inner lead pattern part I2 and the endportion of the first inner lead pattern part I1 may decrease as closerto the horizontal direction (x-axis direction) of the substrate.

A plurality of the first inner lead pattern part I1 may be spaced apartfrom each other by a first distance. One end portion of the second innerlead pattern part I2 may be positioned in a region between two adjacentfirst inner lead pattern parts I1 which are spaced apart from eachother.

In the horizontal direction of the substrate, the end portion of thefirst inner lead pattern part I1 and the end portion of the second innerlead pattern part I2 may be alternately disposed.

Referring to FIG. 11 , on the lower surface of the flexible circuitboard 100 for all-in-one chip on film, the fourth inner lead patternpart I4 and the fourth outer lead pattern part O4 which are one regionof the conductive pattern part CP may be exposed to the outside via thethird open region OA3 of the protection layer 140.

Referring to FIG. 7B and FIGS. 12 to 16 , a chip package including afirst chip C1 and a second chip C2 on a double-side flexible circuitboard 100 all-in-one chip on film according to an embodiment will bedescribed in detail.

FIG. 12 is a schematic plan view of a chip package including adouble-side flexible circuit board 100 for all-in-one chip on filmaccording to an embodiment.

With reference to FIGS. 12A and 12B, the double-side flexible circuitboard 100 for all-in-one chip on film according to the embodiment mayinclude the first chip C1 and the second chip C2 disposed on the sameone surface.

In the double-side flexible circuit board 100 for all-in-one chip onfilm according to the embodiment, a length in a horizontal direction(x-axis direction) may be larger than a length in a vertical direction(y-axis direction). That is, the double-side flexible circuit board 100for all-in-one chip on film according to the embodiment may include twolong sides in the horizontal direction and two short sides in thevertical direction.

Each of the first chip C1 and the second chip C2 may have the length inthe horizontal direction (x-axis direction) larger than the length inthe vertical direction (y-axis direction). That is, the first chip C1and the second chip C2 may include two long sides in the horizontaldirection and two short sides in the vertical direction.

The long side of the double-side flexible circuit board 100 forall-in-one chip on film according to the embodiment may be disposed inparallel with the long side of the first chip C1 and the long side ofthe second chip C2, respectively, and thus a plurality of chips may beefficiently disposed on one double-side flexible circuit board 100 forall-in-one chip on film.

The length in the horizontal direction (long side) of the first chip C1may be larger than the length in the horizontal direction (long side) ofthe second chip C2. The length in the vertical direction (short side) ofthe first chip C1 may be smaller than the length in the verticaldirection (short side) of the second chip C2. Referring to FIG. 13A, thesecond chip C2 may be disposed at a lower portion of the first chip C1.At least a part or all of the long side of the first chip C1 and thelong side of the second chip C2 may be overlapped vertically.

Referring to 13B, the second chip C2 may be disposed on a side portionof the first chip C1. The long side of the first chip C1 and the longside of the second chip C2 may not be overlapped vertically.

The first chip C1 is a drive IC chip, and the second chip C2 may includea second chip C2A of any one of a diode chip, a power supply IC chip, atouch sensor IC chip, an MLCC chip, a BGA chip, and a chip condenser andone second chip C2B different from the any one of the diode chip, thepower supply IC chip, the touch sensor IC chip, the MLCC chip, the BGAchip, the chip condenser.

With reference to FIGS. 13 to 16 , a manufacturing step of a chippackage including a double-side flexible circuit board for all-in-onechip on film according to the embodiment will be described.

FIG. 13 is a plan view of a double-side flexible circuit board 100 forall-in-one chip on film according to the embodiment.

Referring to FIGS. 13A and 13B, the protection layer 140, which ispositioned on one surface of the double-side flexible circuit board 100for all-in-one chip on film according to an embodiment, may include aplurality of holes. That is, the protection layer 140 may include aplurality of open regions.

The first open region OA1 of the protection layer may be a regionexposed to be connected to the first connection part 70. The conductivepattern part CP exposed in the first open region OA1 of the protectionlayer may include pure plating on a surface facing the first connectionpart. That is, in the first open region OA1 of the protection layer, acontent of tin of the second plating layer included in the conductivepattern part CP may be 50 atomic % or more.

The second open region OA2 of the protection layer may be a regionexposed to be connected to the second connection part 80. The conductivepattern part CP exposed in the second open region OA2 of the protectionlayer may include an alloy layer of copper and tin on a surface facingthe second connection part. That is, in the second open region OA2 ofthe protection layer, the content of tin of the second plating layerincluded in the conductive pattern part CP may be less than 50 atomic %.

The first open region OA1 may be a region for connecting a first chip.The first inner lead pattern part I1 extending from the first outer leadpattern part O1 positioned in the third open region OA3 and facing theinside of the first open region OA1 may correspond to or have adifferent width from the first outer lead pattern part O1. For example,a width W1 of the first outer lead pattern part O1 may correspond to awidth W2 of the first inner lead pattern part I1. For example, the widthW1 of the first outer lead pattern part O1 may be larger than the widthW2 of the first inner lead pattern part I1. Specifically, a differencebetween the width W1 of the first outer lead pattern part O1 and thewidth W2 of the first inner lead pattern part I1 may be within 20%.

The first inner lead pattern part I1 and the third inner lead patternpart I3 extending toward the inside of the first open region OA1 mayhave a width corresponding to each other.

The first outer lead pattern part O1 and the second outer lead patternpart O2 extending from the first open region OA1 toward an outerperiphery of the substrate may have a width corresponding to each other.Accordingly, a first chip having a fine line width and requiring a largenumber of first connection parts, and a second chip having a large linewidth and requiring a small number of second connection parts may all bemounted on one flexible circuit board for all-in-one chip on film 100.At this time, the fine line width may mean that a line width of any oneof the first outer lead pattern part O1 and the second outer leadpattern part O2 is smaller than that of any one of a fifth outer leadpattern part O5 and a sixth outer lead pattern part O6. On the otherhand, the large line width may mean that a line width of any one of thefirst outer lead pattern part O1 and the second outer lead pattern partO2 is relatively larger than that of any one of the fifth outer leadpattern part O5 and the sixth outer lead pattern part O6.

The flexible circuit board 100 for all-in-one chip on film may include aplurality of the second open regions OA2 for connecting second chips C2a and C2 b which are different types, respectively.

One of the second open regions OA2 may be a region for connecting onesecond chip C2 a. The fifth outer lead pattern part O5 extending from afifth inner lead pattern part I5 positioned in the second open regionOA2 toward the outer periphery of the substrate may have a differentwidth. For example, a width W3 of the fifth inner lead pattern part I5may be larger than a width W4 of the fifth outer lead pattern part O5.Specifically, the width W3 of the fifth inner lead pattern part I5 maybe larger 1.5 times or more than the width W4 of the fifth outer leadpattern part O5.

Another one of the second open region OA2 may be a region for connectinganother one second chip C2 b. The sixth outer lead pattern part O6extending from a sixth inner lead pattern part I6 positioned in thesecond open region OA2 toward the outer periphery of the substrate mayhave a different width. For example, a width W5 of the sixth inner leadpattern part I6 may be larger than a width W6 of the sixth outer leadpattern part O6. Specifically, the width W5 of the sixth inner leadpattern part I6 may be larger 1.5 times or more than the width W6 of thesixth outer lead pattern part O6.

Any one of the width W3 of the fifth inner lead pattern part I5 and thewidth W5 of the sixth inner lead pattern part I6 exposed through thesecond open region may be greater than the width W2 of the first innerlead pattern part I1 exposed through the first open region. Accordingly,lead pattern parts corresponding to the first and second connectionparts having various sizes/shapes may be formed, thereby improving thedegree of freedom in design. That is, the embodiment may include varioussizes of inner lead pattern parts and various shapes of inner leadpattern parts suitable for different types of the first chip and thesecond chip, thereby enabling an optimal chip package.

A shape of an in-lead pattern positioned below the first chip may bedifferent from that of an in-lead pattern positioned below the secondchip. Accordingly, the embodiment may include in-lead pattern partshaving different shapes, which may have excellent adhesioncharacteristics with the first chip and second chip of different types.Therefore, the flexible circuit board for all-in-one chip on filmaccording to the embodiment may have excellent bonding characteristicsbetween the first chip and the second chip.

That is, different types of the first chip and the second chip aremounted on one substrate, and thus the in-lead pattern part havingdifferent shapes may be an optimal pattern design for ensuring apredetermined bonding strength.

A shape of the first inner lead pattern part I1 in a plane may be asquare stripe pattern. Specifically, the shape of the first inner leadpattern part I1 in the plane may be a square stripe pattern having auniform width and extending in one direction. As an example, widths ofone end and the other end of the first inner lead pattern part I1 may bethe same.

For example, a shape of the fifth inner lead pattern part I5 or thesixth inner lead pattern part I6 in the plane may be a protrusionpattern having various shapes such as a polygonal shape, a circularshape, an elliptical shape, a hammer shape, a T shape, a random shape,and the like. Specifically, the shape of the fifth inner lead patternpart I5 or the sixth inner lead pattern part I6 in the plane has avariable width, and may be a protruding pattern such as a polygonalshape, a circular shape, an elliptical shape, a hammer shape, a T shape,a random shape, and the like extending in a direction different from theone direction. As an example, widths of one end and the other end of atleast one of the fifth inner lead pattern part I5 and the sixth innerlead pattern part I6 may be different from each other. The width of theother end which is an end portion far from the protection layer may belarger than that of the one end of the fifth inner lead pattern part I5and the sixth inner lead pattern part I6 near the protection layer.However, the embodiment is not limited thereto, and of course, the widthof the other end which is the end portion far from the protection layermay be smaller than that of the one end of the fifth inner lead patternpart I5 and the sixth inner lead pattern part I6 near the protectionlayer.

As an example, when the second chip is an MLCC chip, the inner leadpattern part may have a T shape like the fifth inner lead pattern partI5 of FIG. 13B.

As an example, when the second chip is a BGA chip, the inner leadpattern part may be a circular shape like the sixth inner lead patternpart I6 of FIG. 13A. Alternatively, when the second chip is a BGA chip,the inner lead pattern part may be a semicircular shape or a shape inwhich an end is rounded like the sixth inner lead pattern part I6 ofFIG. 13B.

Shapes of the first inner lead pattern part and the first connectionpart may be the same. For example, shapes of planes (top view) of thefirst inner lead pattern part and the first connection part may be aquadrangular shape. Here, the fact that the first inner lead patternpart and the first connection part have the same shape means that thetop view is the same polygon, and may include that sizes are different.

Shapes of the fifth inner lead pattern part and the second connectionpart may be the same or different from each other. Shapes of the sixthinner lead pattern part and the second connection part may be the sameor different from each other.

Referring to FIG. 13B and FIG. 14B, the top view of the fifth inner leadpattern part I5 may be a polygonal shape, and the top view of the secondconnection part may be a circular shape. The top view of the sixth innerlead pattern part I6 may be a circular shape, and the second connectionpart may be a circular shape.

Referring to FIG. 13B and FIG. 14B, the top view of the fifth inner leadpattern part I5 may be a polygonal shape, and the second connection partmay be a quadrangular shape having rounded corners or an ellipticalshape. The top view of the sixth inner lead pattern part I6 may be asemicircular shape, and the second connection part may be a circularshape.

In the top view of the first connection part 70, a horizontal length anda vertical length (aspect ratio) may correspond to each other, or may bedifferent from each other. For example, the top view of the firstconnection part 70 may be a square shape in which the horizontal lengthand the vertical length (aspect ratio) correspond to each other, or maybe rectangular shape in which the horizontal length and the verticallength (aspect ratio) are different from each other.

In the top view of the second connection part 80, the horizontal lengthand the vertical length (aspect ratio) may correspond to each other, ormay be different from each other. For example, the top view of thesecond connection part 80 may be a circular shape in which thehorizontal length and the vertical length (aspect ratio) correspond toeach other, or may be an elliptical shape in which the horizontal lengthand the vertical length (aspect ratio) are different from each other.

A first pitch which is a distance between adjacent the first outer leadpattern parts O1 may be smaller than a second pitch which is a distancebetween adjacent at least one outer lead pattern parts of the fifthouter lead pattern part O5 and the sixth outer lead pattern part O6. Atthis time, the first pitch and the second pitch may refer to an averageseparation distance between two adjacent conductive pattern parts.

The first pitch P1 may be less than 100 μm. For example, the first pitchmay be less than 30 μm. For example, the first pitch may be 1 μm to 25μm.

The second pitch P2 may be 100 μm or more. For example, the second pitchmay be 100 μm to 500 μm. For example, the second pitch may be 100 μm to300 μm.

Accordingly, signal interference between the conductive pattern partsconnected to the first chip and the second chip, respectively may beprevented, and it is possible to improve accuracy of signals.

In the first open region OA1, a plane area of the first inner leadpattern part I1 may correspond to or different from the first connectionpart 70.

The width of the first inner lead pattern part I1 and the width of thefirst connection part 70 may be the same or different within 20%.Accordingly, the first inner lead pattern part I1 and the firstconnection part 70 may be stably mounted. In addition, adhesioncharacteristics between the first inner lead pattern part I1 and thefirst connection part 70 may be improved.

In the second open region OA2, a plane area of any one inner leadpattern part of the fifth inner lead pattern part I5 and the sixth innerlead pattern part I6 may correspond to or different from the secondconnection part 80.

As an example, a width of the second connection part 80 may be larger1.5 times or more than that of any one inner lead pattern part of thefifth inner lead pattern part I5 and the sixth inner lead pattern partI6. Accordingly, adhesion characteristics between any one of the fifthinner lead pattern part I5 and the sixth inner lead pattern part I6 andthe second connection part 80 may be improved.

Referring to FIGS. 14A and 14B, a step of disposing a first connectionpart 70 and a second connection part 80 on a flexible circuit board 100for all-in-one chip on film of an embodiment will be described.

The first connection part 70 may be disposed on the first inner leadpattern part I1 and the third inner lead pattern part I3 exposed throughthe first open region OA1, respectively. For example, the firstconnection part 70 may cover entirely or partially upper surfaces of thefirst inner lead pattern part I1 and the third inner lead pattern partI3.

A total number of a plurality of the first inner lead pattern parts I1disposed to be spaced apart from each other and a plurality of the thirdinner lead pattern parts I3 disposed to be spaced from each other maycorrespond to a number of the first connection part 70.

For example, referring to FIGS. 15A and 15B, the number of the pluralityof the first inner lead pattern parts I1 that are spaced apart from eachother is nine, and the number of the plurality of the third inner leadpattern parts I3 that are spaced apart from each other is nine, and thenumber of the first connection part 70 may be 18 which is the sum ofnine, the number of the first inner lead pattern part I1 and nine, thenumber of the plurality of third inner lead pattern parts I3 that arespaced apart from each other.

The second connection part 80 may be disposed on the fifth inner leadpattern part I5 and the sixth inner lead pattern part I6 exposed throughthe second open region OA2, respectively. For example, the secondconnection part 80 may cover entirely or partially upper surfaces of thefifth inner lead pattern part I5 and the sixth inner lead pattern partI6.

A number of a plurality of the fifth inner lead pattern parts I5disposed to be spaced apart from each other may correspond to a numberof the second connection part 80 disposed on the fifth inner leadpattern part I5.

For example, referring to FIGS. 15A and 15B, the number of a pluralityof the fifth inner lead pattern parts I5 disposed to be spaced apartfrom each other may be two, and the number of the second connection part80 disposed on the fifth inner lead pattern parts I5 may be two.

A number of a plurality of the sixth inner lead pattern part I6 disposedto be spaced apart from each other may correspond to a number of thesecond connection part 80 disposed on the sixth inner lead pattern partI6.

For example, referring to FIGS. 15A and 15B, the number of the pluralityof the sixth inner lead pattern part I6 disposed to be spaced apart fromeach other may be three, and the number of the second connection part 80disposed on the sixth inner lead pattern part I6 may be three.

The second connection part 80 may be larger than the first connectionpart 70. A width of the fifth inner lead pattern parts I5 or the sixthinner lead pattern part I6 exposed through the second open region islarger than that of a first inner lead pattern part I1 exposed throughthe first open region, and thus the second connection part 80 may belarger than the first connection part 70.

A step of disposing the first chip C1 and second chips C2 a and C2 b onthe flexible circuit board 100 for all-in-one chip on film will bedescribed with reference to FIGS. 15A and 15B.

The first chip C1 may be disposed on the first connection part 70.

The second chip C2 may be disposed on the second connection part 80.

The first chip C1 and the second chip C2 may be disposed to be spacedapart at a predetermined distance in order to prevent problems such assignal interference, disconnection failures, failures due to heat, orthe like.

FIG. 16 is a cross-sectional view of a chip package including adouble-side flexible circuit board for all-in-one chip on film accordingto FIGS. 15A and 15B.

The first chip C1 and the second chip C2 may be disposed in differentsizes on the same one surface. For example, the second chip C2 may belarger than the first chip C1.

A via hole may be disposed at a lower portion of the first chip C1 andthe second chip C2. That is, a substrate 110 in a region correspondingto the first open region OA1 and the second open region OA2 may includethe via hole.

An electrical signal of the second chip C2 may be transmitted from theupper surface to the lower surface of the substrate through a conductivematerial disposed in a fourth via hole V4. Accordingly, the embodimentmay include a large number of conductive pattern parts on one substrate.

The flexible circuit board 100 for all-in-one chip on film according tothe embodiment may realize a conductive pattern part with a fine pitchon both surfaces thereof, and thus it may be suitable for an electronicdevice having a high-resolution display portion.

In addition, the flexible circuit board 100 for all-in-one chip on filmaccording to the embodiment is flexible, small in size, and thin inthickness, and thus it may be used for various electronic devices.

For example, referring to FIG. 17 , the flexible circuit board 100 foran all-in-one chip on film according to the embodiment may be reduced abezel, and thus it may be used for an edge display.

For example, referring to FIG. 18 , the flexible circuit board 100 forall-in-one chip on film according to the embodiment may be included in afordable flexible electronic device. Therefore, the touch deviceincluding the same may be a flexible touch device. And thus, a user mayfold or bend by hand. Such a flexible touch window may be applied to awearable touch device or the like.

For example, referring to FIG. 19 , a flexible circuit board 100 forall-in-one chip on film according to an embodiment may be applied tovarious electronic devices to which a foldable display device isapplied. Referring also to FIGS. 19A to 19C, the foldable display devicemay fold a foldable cover window. The foldable display device may beincluded in various portable electronic products. Specifically, thefoldable display device may be included in a mobile terminal (mobilephone), a notebook (portable computer), and the like. Accordingly, whileincreasing the display region of a portable electronic product, a sizeof the device may be reduced during storage and transportation, and thusportability may be improved. Therefore, convenience of a user of theportable electronic product may be improved. However, the embodiment isnot limited thereto, and of course, the foldable display device may beused for various electronic products.

Referring to FIG. 19A, a foldable display device may include one foldingregion in a screen region. For example, the foldable display device mayhave a C-shape in a folded form. That is, in the foldable displaydevice, one end and the other end opposite to the one end may beoverlapped with each other. At this time, the one end and the other endmay be disposed close to each other. For example, the one end and theother end may be disposed to face each other.

Referring to 19B, a foldable display device may include two foldingregions in a screen region. For example, the foldable display device mayhave a G-shape in a folded form. That is, the foldable display devicemay be overlapped with each other by folding one end and the other endopposite to the one end in a direction corresponding to each other. Atthis time, the one end and the other end may be spaced apart from eachother. For example, the one end and the other end may be disposed inparallel to each other.

Referring to FIG. 19C, a foldable display device may include two foldingregions in a screen region. For example, the foldable display device mayhave an S-shape in a folded form. That is, in the foldable displaydevice, one end and the other end opposite to the one end may be foldedin different directions. At this time, the one end and the other end maybe spaced apart from each other. For example, the one end and the otherend may be disposed in parallel to each other.

In addition, although not shown in the drawings, of course, a flexiblecircuit board 100 for all-in-one chip on film according to an embodimentmay be applied to a rollable display.

Referring to FIG. 20 , a flexible circuit board 100 for all-in-one chipon film according to an embodiment may be included in various wearabletouch devices including a curved display. Therefore, an electronicdevice including the flexible circuit board 100 for all-in-one chip onfilm according to the embodiment may be reduced in thickness, size andweight.

Referring to FIG. 21 , a flexible circuit board 100 for all-in-one chipon film according to an embodiment may be used for various electronicdevices having a display portion such as a TV, a monitor, and a laptopcomputer.

However, the embodiment is not limited thereto, and of course, theflexible circuit board for all-in-one chip on film 100 according to theembodiment may be used for various electronic devices having a flatplate or a curved-shaped display portion.

According to an embodiment of the present invention, different types offirst and second chips may be mounted on one flexible circuit board, andthus the embodiment may provide a chip package including a flexiblecircuit board for all-in-one chip on film with improved reliability.

According to an embodiment of the present invention, a display panel anda main board are directly connected by one flexible circuit board forall-in-one chip on film, and thus a size and thickness of the flexiblecircuit board for transmitting a signal generated from the display panelto the main board may be reduced, and accordingly, it is possible toincrease spaces of other components and/or a battery space.

According to an embodiment of the present invention, since connection ofa plurality of printed circuit boards is not required, convenience of aprocess and reliability of electrical connection may be improved, andaccordingly, it is possible to provide a flexible circuit board forall-in-one chip on film suitable for an electronic device having ahigh-resolution display unit.

In addition, according to an embodiment of the present invention, adummy pattern is disposed at a second surface of a substrate tocorrespond to a circuit pattern disposed on a first surface of thesubstrate, and a dummy pattern is disposed at the first surface of thesubstrate so as to correspond to a circuit pattern disposed on thesecond surface of the substrate, and thus it is possible to solve aproblem of solder resist not being applied or a problem of pinholes thatoccurs when printing the solder resist of the first surface or thesecond surface of the substrate.

The characteristics, structures and effects described in the embodimentsabove are included in at least one embodiment but are not limited to oneembodiment. Furthermore, the characteristic, structure, and effectillustrated in each embodiment may be combined or modified for otherembodiments by a person skilled in the art. Thus, it should be construedthat contents related to such a combination and such a modification areincluded in the scope of the present invention.

In addition, embodiments are mostly described above. However, they areonly examples and do not limit the present invention. A person skilledin the art may appreciate that several variations and applications notpresented above may be made without departing from the essentialcharacteristic of embodiments. For example, each component specificallyrepresented in the embodiments may be varied. In addition, it should beconstrued that differences related to such a variation and such anapplication are included in the scope of the present invention definedin the following claims.

What is claimed is:
 1. A flexible circuit board comprising: a substrate;a first conductive pattern part disposed on a first surface of thesubstrate; a second conductive pattern part disposed on a second surfaceopposite to the first surface of the substrate; a first dummy patternpart disposed in a region of the second surface of the substrate inwhich the second conductive pattern part is not disposed; a firstprotection layer disposed on the first conductive pattern part; and asecond protection layer disposed on the second conductive pattern partand the first dummy pattern part, wherein the first conductive patternpart at an outermost periphery of the substrate is covered by the firstprotection layer, and wherein the first dummy pattern part includes: afirst wiring pattern layer, and a first plating layer including tin (Sn)disposed on the first wiring pattern layer.
 2. The flexible circuitboard of claim 1, wherein the first dummy pattern part is verticallyoverlapped with the first conductive pattern part disposed at theoutermost periphery of the substrate and the first protection layer. 3.The flexible circuit board of claim 1, further comprising a second dummypattern part which is disposed in a region of the first surface of thesubstrate in which the first conductive pattern part is not disposed andat least a part of which is vertically overlapped with the secondconductive pattern part.
 4. The flexible circuit board of claim 3,wherein the first surface is an upper surface of the substrate, thesecond surface is a lower surface of the substrate, and a left side ofthe first dummy pattern part is positioned closer to a left end of thesubstrate than a left side of the first conductive pattern part disposedon the leftmost side of the first conductive pattern part.
 5. Theflexible circuit board of claim 3, wherein a right side of the seconddummy pattern part is positioned closer to a right end of the substratethan a right side of the second conductive pattern part disposed on therightmost side of the second conductive pattern part.
 6. The flexiblecircuit board of claim 3, wherein the second dummy pattern part includesa second wiring pattern layer, and a second plating layer including tin(Sn) disposed on the second wiring pattern layer.
 7. The flexiblecircuit board of claim 6, wherein the first and second dummy patternparts have the same layer structure as the first and second conductivepattern parts.
 8. The flexible circuit board of claim 7, wherein thefirst plating layer of the first dummy pattern part includes: afirst-first plating layer disposed on the first wiring pattern layer,and a first-second plating layer disposed on the first-first platinglayer, wherein the second plating layer of the second dummy pattern partincludes: a second-first plating layer disposed on the second wiringpattern layer, and a second-second plating layer disposed on thesecond-first plating layer.
 9. The flexible circuit board of claim 3,wherein a position in which the second conductive pattern part isstarted initially at the second surface of the substrate is the same asa position in which the second dummy pattern part is started initiallyat the first surface of the substrate.
 10. The flexible circuit board ofclaim 1, wherein a position in which the first conductive pattern partis started initially at the first surface of the substrate is fartherthan a position in which the first dummy pattern part is startedinitially at the second surface of the substrate.
 11. A chip packagewhich comprises a flexible circuit board, the flexible circuit boardcomprising: a substrate; a first conductive pattern part disposed on afirst surface of the substrate; a second conductive pattern partdisposed on a second surface opposite to the first surface of thesubstrate; a first dummy pattern part disposed in a region of the secondsurface of the substrate in which the second conductive pattern part isnot disposed; a first protection layer disposed on the first conductivepattern part; a second protection layer disposed on the secondconductive pattern part and the first dummy pattern part, a chipdisposed on the first conductive pattern part or the second conductivepattern part, wherein the first conductive pattern part at an outermostperiphery of the substrate is covered by the first protection layer, andwherein the first dummy pattern part includes: a first wiring patternlayer, and a first plating layer including tin (Sn) disposed on thefirst wiring pattern layer.
 12. The chip package of claim 11, whereinthe flexible circuit board further comprises: a second dummy patternpart which is disposed in a region of the first surface of the substratein which the first conductive pattern part is not disposed and at leasta part of which is vertically overlapped with the second conductivepattern part, wherein the second dummy pattern part includes a secondwiring pattern layer, and a second plating layer including tin (Sn)disposed on the second wiring pattern layer, wherein the firstconductive pattern part has the same layer structure as the second dummypattern part, and wherein the second conductive pattern part has thesame layer structure as the first dummy pattern part.
 13. The chippackage of claim 12, wherein the first surface is an upper surface ofthe substrate, the second surface is a lower surface of the substrate,wherein the first dummy pattern part is disposed more to the left thanthe second conductive pattern part disposed on the leftmost side of thesecond conductive pattern part, and wherein the second dummy patternpart is disposed more to the right than the first conductive patternpart disposed on the rightmost side of the first conductive patternpart.
 14. The chip package of claim 13, wherein the first dummy patternpart is disposed more to the left than the first conductive pattern partdisposed on the leftmost side of the first conductive pattern part, andthe second dummy pattern part is disposed more to the right than thesecond conductive pattern part disposed on the rightmost side of thesecond conductive pattern part.
 15. The chip package of claim 12,wherein an end portion of the first dummy pattern part disposed on theleftmost side of the first dummy pattern part is aligned on a verticalline with an end portion of the first conductive pattern part disposedon the leftmost side of the first conductive pattern part, and an endportion of the second dummy pattern part disposed on the rightmost sideof the second dummy pattern part is aligned on a vertical line with anend portion of the second conductive pattern part disposed on therightmost side of the second conductive pattern part.
 16. The chippackage of claim 12, wherein a position in which the first conductivepattern part is started initially at the first surface of the substrateis the same as a position in which the first dummy pattern part isstarted initially at the second surface of the substrate.
 17. The chippackage of claim 12, wherein a position in which the first conductivepattern part is started initially at the first surface of the substrateis farther than a position in which the first dummy pattern part isstarted initially at the second surface of the substrate.
 18. The chippackage of claim 12, wherein a position in which the second conductivepattern part is started initially at the second surface of the substrateis the same as a position in which the second dummy pattern part isstarted initially at the first surface of the substrate.
 19. The chippackage of claim 12, wherein a position in which the second conductivepattern part is started initially at the second surface of the substrateis farther than a position in which the second dummy pattern part isstarted initially at the first surface of the substrate.